JP2005012289A - Image scanner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image scanner capable of properly compensating a color blur generated in a high contrast section. <P>SOLUTION: An original S is monitored in transfer by a sensor 32. A microcomputer 100 measures a movement amount of conveying an original from an output of the sensor 32, corresponding to position using the end of the original as a reference, and notifies a microcomputer 120 of the position and the moving amount when the moving amount is equal to or more than a predetermined amount. The microcomputer 120 notifies an image processing IC 125 of the notified position as a color blur candidate position and a color blur correcting amount determined from the notified moving amount. The IC 125 detects color blur in the high contrast section within an achromatic region for the image data corresponding to the color blur candidate position of the image data converted by an image sensor 53, and corrects the color blur of the image data, according to a color blur correction amount determined by the microcomputer 120 from the movement amount. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

【００４２】
（２）図６（Ｂ）に示すように、Ｌ^＊ａ^＊ｂ^＊表色系の色度図では、ａ^＊軸とｂ^＊軸が直交しており、直交点が無彩色点となる。ａ^＊値、ｂ^＊値の範囲を決定することで、無彩色領域を抽出することができる。色滲みがないときは、カラーとモノクローム（以下、モノクロという。）との分離を行なうのは容易であるが、色滲みがあるときは、カラーと色滲みとの特徴が良く似ており、画素単位でカラーとモノクロとの分離を行なうのは難しい（色彩のみでカラーと色滲みとを分離することは難しい）ため、例えば、以下のアルゴリズムで無彩色領域を検出する。
【００４３】
▲１▼ 画像データを、累積ヒストグラムを作成するために、ｍ×ｍ（例えば、８画素×８画素）毎の小領域に分割する。
▲２▼ ▲１▼の小領域において、主走査方向に相当する縦方向にａ^＊値とｂ^＊値の累積ヒストグラムを作成する。ただし、累積値は累積画素数で正規化する。
▲３▼ ▲２▼での累積値が、Ｔａ_ＳＬ＜ａ^＊＜Ｔａ_ＳＨ、かつ、Ｔｂ_ＳＬ＜ｂ^＊＜Ｔｂ_ＳＨの値の範囲に入るものを無彩色領域として検出する。
▲４▼ ▲３▼で無彩色領域と判別されなかった部分についてのみ、副走査方向に相当する横方向にａ^＊値とｂ^＊値の累積ヒストグラムを作成する。ここでも、累積値は累積画素数で正規化する。
▲５▼ ▲４▼での累積値が、Ｔａ_ＭＬ＜ａ^＊＜Ｔａ_ＭＨ、かつ、Ｔｂ_ＭＬ＜ｂ^＊＜Ｔｂ_ＭＨの値の範囲に入るものも無彩色領域として検出する。
【００４４】
（３）色滲みは原稿Ｓの搬送方向（副走査方向）に生ずるため、図７（Ａ）に示す３×３の垂直方向Ｓｏｂｅｌフィルタを用いて無彩色領域での横方向の高コントラスト部（エッジ部）を検出する。すなわち、画像データのマトリクスの中央をＭ（ｉ，ｊ）とすると、Ｓｏｂｅｌフィルタ処理後のマトリクスの中央の値Ｍ（ｉ，ｊ）’は、Ｍ（ｉ，ｊ）’＝Ｍ（ｉ−１，ｊ−１）×（−１）＋Ｍ（ｉ，ｊ−１）×（−２）＋Ｍ（ｉ＋１，ｊ−１）×（−１）＋Ｍ（ｉ−１，ｊ）×０＋Ｍ（ｉ，ｊ）×０＋Ｍ（ｉ＋１，ｊ）×０＋Ｍ（ｉ−１，ｊ＋１）×１＋Ｍ（ｉ，ｊ＋１）×２＋Ｍ（ｉ＋１，ｊ＋１）×１として演算することができる。従って、例えば、図７（Ｂ）に示す画像データでは、左側のマトリクスの中央の値Ｍ（ｉ，ｊ）’は１６として求められ、右側のマトリクスの中央の値Ｍ（ｉ，ｊ）’は０として求められる。なお、本実施形態の画像読取装置では、原稿Ｓの搬送方向に色滲みを生ずるため横方向の高コントラスト部を検出しているが、縦方向（副走査方向）にアルゴリズムを変更しても、両方を併用してもよい。
【００４５】
（４）色滲みは、無彩色領域内の高コントラスト部（エッジ部）において、各画素におけるａ^＊値、ｂ^＊値がＴａ_ＤＬ＜ａ^＊＜Ｔａ_ＤＨ、又は、Ｔｂ_ＤＬ＜ｂ^＊＜Ｔｂ_ＤＨの範囲以外の画素に生じており、この画素を色滲み画素として判別することができ、画像データから色滲み画素の位置も特定することができる。つまり、無彩色領域内において対象画素周辺の画素（周辺画素）がカラーの場合には周辺画素が色滲みとして検出される。下表１には、色滲み検出で用いられる各閾値が纏められている。
【００４６】
【表１】

【００４７】
マイコン１２０は画像処理ＩＣ１２５に色滲みが発生候補位置を色滲み候補位置情報として画像処理ＩＣ１２５に報知し、画像処理ＩＣ１２５は、色滲み候補位置に対して上述した（１）〜（４）を実行することで色滲みの検出を実行する。
【００４８】
画像データの色滲みは、副走査方向におけるイメージセンサ５３の走査が一定速度でなく、かつ、ＲＧＢの読み取りが時間的に同時でないことに起因する。つまり、ある時刻に原稿Ｓの搬送変動が発生した場合にＲＧＢの画像データに影響（画像の一部の伸縮）が現れるが、同時に読み取っていない場合には、ＲＧＢそれぞれ別の位置に搬送変動の影響が現れる。例えば、白から黒に変化するエッジ部でＲが伸びる場合には、エッジ部に赤い部分（色滲み）が発生する。これを補正するには、色滲みが発生した部分で画像が伸びたか、又は、縮んだかとその伸縮量（補正すべき伸縮量）とを計量し、伸びた場合は伸びた分の画像を縮め（副走査方向に縮小し）、縮んだ場合は縮んだ分を伸ばせばよい（副走査方向に拡大すればよい）。
【００４９】
マイコン１２０は、マイコン１００より受信したズレ情報のうち変動量から、補正すべき伸縮量を演算（決定）し、画像処理ＩＣ１２５に補正すべき位置及び補正すべき伸縮量を報知する。マイコン１２０のＲＡＭに、予め変動量−伸縮量テーブルを展開しておき、ＲＡＭに記憶された当該位置に対応する変動量を読み出して、変動量−伸縮量テーブルを参照することで、補正すべき伸縮量を演算してもよい。
【００５０】
この報知を受けた画像処理ＩＣ１２５は、ＲＧＢ毎にマイコン１２０から報知された補正すべき位置及び補正すべき伸縮量に従って画像データを補正した後、イメージセンサ５３を構成するカラーセンサ間の離間を是正する時間差補正及びＲＧＢを重ね合わせてカラー画像データとする画像処理を行う。このように処理された画像データは、通信ＩＣ１２６を介して外部装置へ送出され、最終ラインの画像データの送信終了により１枚分の原稿Ｓの読み取りが終了する。なお、シートスルーモードによる原稿Ｓの読み取りは、載置トレイ２２に原稿が存在しないことをエンプティセンサが検出するまで、又は、外部装置から読取中止命令を受信するまで、上述した原稿繰出時に戻って載置トレイ２２に載置された次の原稿について続行される。
【００５１】
（作用等）
次に、本実施形態の画像読取装置の作用等について説明する。
【００５２】
本実施形態の画像読取装置では、マイコン１２０が、搬送計測ユニット３０及びマイコン１００の共働による原稿Ｓの搬送方向でのズレ情報（位置情報に対応する挙動情報）を把握し、ズレ情報のうち位置情報を色滲み候補位置情報として画像処理ＩＣ１２５に報知するので、画像処理ＩＣ１２５はＲＧＢ別の画像データの全領域につて色滲み検出を行う必要がなく、報知された領域に限定して色滲み検出を行う。つまり、本実施形態では、原稿Ｓの搬送変動を計測して異常な搬送を検出したときに、色滲みを発生させる要因があるとしてその色滲み候補位置を仮定し、この部分に対して画像データの色滲み検出を実行し、確かに色滲みが存在すればそこは正しい色滲み位置であるとみなすこととした。このため、従来技術のように、画像処理ＩＣ１２５がＲＧＢの各画像データの全ての画素について色滲み検出を行う必要がない。従って、本実施形態の画像読取装置は、色滲み検出に膨大な計算負荷が掛からずリアルタイムに色滲み検出を行うことができる。
【００５３】
また、本実施形態では、原稿Ｓの搬送変動が生じると当該箇所の画像データに色滲みが発生するという原理に着目して、マイコン１００、１２０、変動量検出回路３８及び画像処理ＩＣ１２５の共働により、ＲＧＢの各画像データに対し画像処理ＩＣ１２５で検出された色滲み位置に対応した、変動量検出回路３８が生成したズレ情報のうち挙動情報（変動量）に応じて各画像データの色滲みを補正する。このため、カラー画像データのみを解析する従来技術のように、正しく色が挿入された画像データに対して色滲みと誤判定することない。従って、本実施形態の画像読取装置は、原稿Ｓの搬送変動に起因する画像データの色滲みを正しく補正することができる。
【００５４】
更に、本実施形態では、搬送計測ユニット３０のイメージセンサ３２に１０ライン離間した原稿Ｓの搬送方向と交差する方向（副走査方向）に長い２本のラインセンサを用い、１ライン毎に原稿Ｓの搬送変動を非接触で監視している。このため、原稿Ｓの搬送に影響を与えることなく搬送変動を正確に計測することができる。従って、マイコン１２０は、画像データの色滲みに対して補正すべき伸縮量を正しく決定でき、その結果、画像処理ＩＣ１２５による画像データの色滲みを正しく補正することができる。換言すれば、本実施形態の画像読取装置から通信ＩＣ１２６を介して外部装置に送出される画像データの質を高めることができる。
【００５５】
また、本実施形態では、搬送計測ユニット３０に発光ダイオード３４を有したアクティブ方式のものを例示したが、図３に示すように、図２に示した発光ダイオード３４に相当する構成を欠くパッシブ方式の搬送計測ユニット１３０を用いるようにしてもよい。すなわち、搬送計測ユニット１３０は、原稿Ｓを透過した透過光を集光するレンズ１３３、１０ライン離間した２本のラインセンサを有するイメージセンサ１３２、イメージセンサ１３２を作動させる作動回路、イメージセンサ１３２からの出力を増幅するアンプ及びアンプからの出力を変換するＡ／Ｄコンバータ等がマウントされたユニット基板１３１を有しており、これらの構成部品は振動等による影響を抑制するためにユニットフレーム１３５に一体となって固定されている。この搬送計測ユニット１３０では、２本のラインセンサ間の中央が監視位置Ｐｗとされており、監視位置Ｐｗと読取位置Ｐｒとは一致している。従って、上流側及び下流側ラインセンサが１０ライン離間している場合は、それぞれ、頭出しセンサ８０が原稿Ｓの先端を検出する位置から３９５ライン目、４０５ライン目に配置される。このような構成では、透過光を用いることから原稿Ｓを構成する繊維も画情報に含まれるため、精度よく原稿Ｓの搬送変動を計測することができる。また、別の光源を必要としないため、読取画像に影響を与えないことと、読取位置での原稿の挙動が検出できるため正確に変動が検出できることも利点として上げられる。
【００５６】
更に、本実施形態では、画像処理ＩＣ１２５が実行する色滲み検出にＣＩＥＬ^＊ａ^＊ｂ^＊変換法を例示したが、本発明はこれに限定されるものではなく、例えば、ＲＧＢのうち少なくとも１色の輝度値が他の多くとも２色の輝度値と大きく異なることに着目するＲＧＢ３原色からの色彩による色彩法や色の相関を使用する相関法等を用いるようにしてもよく、このような色滲み検出法でも「カラー画像データの無彩色領域内の高コントラスト部に存在する色滲みの位置を検出する」ことができる。これらの色滲み検出法の詳細については、本出願人が平成１４年２月１９日に出願した特願２００２−０８９９２８に詳しい。
【００５７】
また、本実施形態では、原稿搬送の変動量を２本のラインセンサからの出力を比較して画情報の差異により計測する例を示したが、本発明はこれに制限されず、例えば、原稿Ｓの速度を計測して速度差を原稿搬送の変動量とするようにしてもよい。また、本実施形態のようにアクティブ方式を用いる場合に、レーザー光を照射させ、あるいは、光に限定されず、超音波を含む音を発生させドップラー効果を利用した速度変化を検出するようにしてもよい。
【００５８】
更に、本実施形態では、マイコン１００、１２０、変動量検出回路３８、画像処理ＩＣ１２５に分けて説明したが、本発明はこれに限定されず、例えば、これらを１つのマイコンと１つの画像処理ＩＣで行うようにしてもよく、変動量検出回路３８、画像処理ＩＣ１２５が実行する画像処理をマイコンが実行するようにしてもよい。また、本実施形態では、マイコン１００、１２０、変動量検出回路３８、画像処理ＩＣ１２５の共動で行う例を示したが、これらマイコン１００、１２０の処理も含めてハードウエアで構成するようにしてもよい。
【００５９】
そして、本実施形態では、原稿搬送ユニット１と画像読取ユニット２とを別体構成とした例を示したが、固定原稿による読み取りを行わずシートスルーモードの読み取りのみを行うようにすれば、固定原稿プラテンガラス７３は不要であり原稿読取装置全体の投影面積がかなり小さく構成でき、搬送障害の解除等は別とすると一体構成が可能である。
【００６０】
【発明の効果】
以上説明したように、本発明によれば、原稿の搬送変動が生じると当該箇所のカラー画像データに色滲みが発生するという原理に着目して、画像データ補正手段により色滲み検出手段で検出された色滲み位置のうち前記計測手段で計測された位置に対応したカラー画像データを計測手段で計測された変動量に基づいて補正するので、カラー画像データのみを解析する従来技術に比べて、正しく色が挿入された画像データに対して色滲みと誤判定することなく、カラー画像データの色滲みを補正することができる、という効果を得ることができる。
【図面の簡単な説明】
【図１】本発明が適用可能な画像読取装置の実施形態の概略正断面図である。
【図２】実施形態の画像読取装置の流し読みプラテンガラス近傍の正断面図である。
【図３】他の実施形態の画像読取装置の流し読みプラテンガラス近傍の正断面図である。
【図４】実施形態の画像読取装置の概略ブロック回路図である。
【図５】実施形態の画像読取装置の色滲み補正に関連する動作を模式的に示す動作説明図である。
【図６】（Ａ）はイメージセンサで読み取った読取画像に含まれる画像データの分類を模式的に示す説明図、（Ｂ）はＣＩＥＬ^＊ａ^＊ｂ^＊法での知覚色度と色との関係を模式的に示す説明図ある。
【図７】（Ａ）はＣＩＥＬ^＊ａ^＊ｂ^＊法での原稿搬送方向に対する色滲み発生エッジと垂直方向Ｓｏｂｅｌフィルタを示す説明図、（Ｂ）は画像データの例を示す説明図である。
【符号の説明】
１ 原稿搬送ユニット（画像読取装置の一部）
２ 画像読取ユニット（画像読取装置の一部）
３ 排紙トレイ
３ａ カバー
１０ ピックアップローラ（搬送手段の一部）
１１ 分離ローラ（搬送手段の一部）
１２ 搬送ローラ（搬送手段の一部）
１３ 搬送コロ（搬送手段の一部）
１４ 排出ローラ（搬送手段の一部）
１５ 排出コロ（搬送手段の一部）
１６ 分離パッド
１７ バネ
２０ 排紙モータ
２１ ガイド板
２２ 載置トレイ
３０ 搬送計測ユニット（監視センサ）
３２ イメージセンサ（監視センサ受光素子）
３３ レンズ（監視センサ）
３４ 発光ダイオード（監視センサ発光素子）
３５ フレームユニット
５０ 第一キャリッジ
５１ 第二キャリッジ
５２ レンズユニット
５３ イメージセンサ
５４ アナログ基板
５５ 画像処理基板
５６ インターフェースコネクタ
６０ 照明用ランプ（光源）
６１ 第一ミラー
６２ 第二ミラー
６３ 第三ミラー
６４ リフレクタ
７０ 原稿ガイド（すくい上げ）
７１ 原稿ガイド（すくい上げ）
７２ 流し読みプラテンガラス
７３ 固定原稿プラテンガラス
７５ ケーシング
８０ 頭出しセンサ（先端検出センサ）
１００ マイコン（計測手段の一部）
１０１ ドライバ
１０２ ＡＤＦコネクタ
１２０ マイコン（画像データ補正手段の一部）
１２２ Ａ／Ｄコンバータ
１２３ シェーディング補正処理部
１２４ クロックジェネレータ
１２５ 画像処理ＩＣ（色滲み検出手段、画像データ補正手段の一部）
１２６ 通信ＩＣ
１２８ スキャナコネクタ
１３０ 搬送計測ユニット
１３１ ユニット基板（監視センサー）
１３２ イメージセンサ（監視センサー受光素子）
１３３ レンズ（監視センサー）
１３５ ユニットフレーム（監視センサー）
Ｓ 原稿
Ｐｒ 読取位置
Ｐｗ 監視位置[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image reading apparatus, and more particularly to an image reading apparatus that reads a conveyed document at a predetermined reading position.
[0002]
[Prior art]
Conventionally, in an image reading apparatus equipped with a document conveyance unit such as a scanner, an image sensor that reads a document is stopped at a predetermined reading position, and the document conveyed by the document conveyance unit is read through a reading glass. The image data is acquired with (sheet through method). That is, in the sheet-through method, the document transport unit separates the document placed on the paper feed tray, and then separates the separated document by rollers disposed on the upstream side and the downstream side with respect to the reading glass. It is conveyed to the reading position on the reading glass. The document read at the reading position is picked up from the reading glass by a scooping member fixed to the document transport unit or the image reading device, and is discharged to a downstream discharge tray. The image reading device irradiates light from a light source, guides the light reflected by the image recording surface of the document conveyed to the reading position to an image sensor through an optical system such as a mirror or a lens, and outputs image data by photoelectric conversion. get.
[0003]
However, when the document is transported from the reading glass, the leading edge of the document hits the surface of the fixed scooping member or the transport roller arranged on the downstream side of the reading glass. It receives a reaction force (impact) in the direction opposite to the conveying direction. Due to this impact, the document is instantaneously stopped or vibrated at the reading position, and the read image data includes position distortion. Further, when the rear end of the document in the conveyance direction passes through a conveyance roller arranged on the upstream side of the reading glass, the document at the reading position flutters and blurs at the moment when the grip (clamping) of the roller with respect to the document is released. For this reason, there is a problem that the read image data includes positional distortion and the quality of the image data is deteriorated. In particular, in a color image reading apparatus in which the reading sensor is composed of three lines of RGB three primary colors, the positions at which the original is read simultaneously are different. It will be reproduced.
[0004]
In order to solve this problem, the degree of color is detected from the acquired image data by using a correlation operation between the image data of the three primary colors of RGB, and it is detected whether there is any color blur at the black and white boundary that should originally be monochrome. Thus, there is disclosed a technique for correcting (see, for example, Patent Document 1).
[0005]
[Patent Document 1]
JP-A-8-139949
[0006]
[Problems to be solved by the invention]
However, the color image recorded on the original is quite different, and even if the technique of the above patent document is used, for example, the color is correctly inserted in the high contrast portion from white to black such as the edge portion and the boundary. Image data may be erroneously detected, and a defect of missing colors may occur. In addition, in the color blur detection method for detecting the color portion by calculating the saturation of all achromatic (monochrome) regions of the image data, a large calculation performance is required for real-time color blur detection processing due to a huge amount of calculation.
[0007]
An object of the present invention is to provide an image reading apparatus capable of appropriately correcting color blur generated in a high contrast portion while suppressing the amount of calculation for color blur detection.
[0008]
[Means for Solving the Problems]
In order to solve the above-described problems, the present invention provides a conveyance unit that conveys a document, a light source that irradiates a document surface conveyed by the conveyance unit, and an image sensor that converts light from the document surface into color image data. A measuring means for measuring a variation amount and a position of the document conveyance by an output from a monitoring sensor for monitoring the document conveyed by the conveyance means, and an achromatic region of the color image data converted by the image sensor. Color blur detection means for detecting the position of color blur existing in a high contrast portion, and color image data corresponding to the position measured by the measurement means among the color blur positions detected by the color blur detection means Image data correction means for correcting based on the variation measured by the means.
[0009]
In the present invention, the original is conveyed by the conveying means, and the light irradiated from the light source onto the original surface enters the image sensor and is converted into color image data. The document transported by the transport unit is monitored by the monitoring sensor for the transport state, and the variation amount and the position of the document transport are measured from the output of the monitoring sensor by the measuring unit. On the other hand, the position of the color blur existing in the high contrast portion in the achromatic region of the color image data converted by the image sensor by the color blur detection means is detected. The color image data corresponding to the position measured by the measuring means among the color blur positions detected by the color blur detecting means by the image data correcting means is based on the variation amount measured by the measuring means and the position. It is corrected. According to the present invention, paying attention to the principle that color blur occurs in the color image data at the location when the document transport fluctuation occurs, out of the color blur positions detected by the color blur detection unit by the image data correction unit. Since the color image data corresponding to the position measured by the measurement unit is corrected based on the amount of variation measured by the measurement unit, an image in which a color is correctly inserted is compared with the conventional technique that analyzes only the color image data. The color blur of the color image data can be corrected without erroneously determining that the data is a color blur.
[0010]
In the present invention, either an active method or a passive method may be used for the monitoring sensor. That is, the monitoring sensor may be configured to include a light emitting element that emits light and a light receiving element that receives reflected light from the back side of the document, which is disposed on the back side opposite to the document surface, or It may be configured by a light receiving element that is disposed on the back side opposite to the original surface and receives transmitted light that is irradiated from the light source and transmitted through the original. At this time, the measuring unit may measure at least two received light signals obtained from the light receiving elements at different times to measure the fluctuation amount of the document conveyance, or may use not only light but also an ultrasonic wave or the like. Further, a leading edge detection sensor for detecting the leading edge in the document conveyance direction may be provided, and the amount of variation in document conveyance may be measured corresponding to position information with the document leading edge detected by the leading edge detection sensor as a reference.
[0011]
In this case, the measuring means determines whether or not the variation amount of the document conveyance corresponding to the position information exceeds a predetermined amount, and when it determines that the amount exceeds the predetermined amount, the position information is subjected to color bleeding. The detection unit is informed as a candidate position where color blur occurs, and the color blur detection unit exists in a high-contrast portion in the achromatic region of the color image data corresponding to the position information notified from the measurement unit in the color image data. If the position of the color blur to be detected is detected, the color blur detection unit does not need to detect the color blur position for all color image data, so the color blur detection process is processed in real time with a relatively small amount of calculation. It becomes possible to do. The image data correction unit corrects the color image data at the color blur position detected by the color blur detection unit when the fluctuation amount of the document conveyance measured by the measurement unit exceeds a predetermined amount set in advance. In addition, the correction amount of the color image data may be determined according to the variation amount of the document conveyance measured by the measuring unit.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of an image reading apparatus according to the present invention will be described below with reference to the drawings.
[0013]
(Constitution)
As shown in FIG. 1, the image reading apparatus of this embodiment reads an original and outputs an image reading unit 2 that can output color image data to an external device such as a personal computer. And a document transport unit 1 for transporting a target document.
[0014]
The image reading unit 2 has a substantially box-shaped casing 75. The upper part of the casing 75 has a fixed original platen glass 73 that serves as an original placement table when reading a fixed original, and a flow reading platen that is used when reading an original in a sheet-through mode using the original conveyance unit 1. The glass 72 is fixed. In the vicinity of both sides of the flow reading platen glass 72, document guides 70 and 71 having a substantially triangular cross section that protrude toward the document transport unit 1 and support the image recording surface side of the document S to be transported are formed integrally with the casing 75. (See also FIG. 2).
[0015]
In addition, the image reading unit 2 includes a first carriage 50 and a second carriage 51 that can move in the sub-scanning direction (perpendicular to the scanning direction of the image sensor) in the casing 75 by the driving force of a stepping motor (not shown). Have. The first carriage 50 includes an illumination lamp 60 for illuminating the document S, a reflector 64 that reflects light from the illumination lamp 60 in the document direction, and a first mirror 61 that changes the optical path of the reflected light from the document. The second carriage 51 has a second mirror 62 that changes the optical path of the reflected light from the original that has been changed by the first mirror 61 to be substantially vertical, and the reflected light that has been changed by the second mirror 62. And a third mirror 63 having a substantially horizontal optical path. On the horizontal extension line of the third mirror 63, a lens unit 52 that condenses the reflected light on the sensor surface of a linear color image sensor 53 such as a CCD is disposed.
[0016]
The image sensor 53 is mounted on an analog substrate 54 that operates the image sensor 53 and converts an analog signal from the image sensor 53 into a digital signal. The analog substrate 54 is connected to a processing substrate 55 that performs shading correction processing, image processing, and the like. The processing substrate 55 is connected to an interface connector 56 that is fixed to the casing 75 and allows connection with an external device.
[0017]
That is, as shown in FIG. 4, the analog substrate 54 is mounted with an image sensor 53, a clock generator 124 that operates the image sensor 53, and an A / D converter 122. A microcomputer (hereinafter referred to as a microcomputer) 120 that controls the entire unit 2, a shading correction processing unit 123 that corrects uneven density of image data, an image that performs image processing such as time difference correction of image data and color blur correction described later. A processing IC 125 and a communication IC 126 for controlling communication with an external device are mounted. The microcomputer 120 is connected to the document conveying unit 1 via the scanner connector 128.
[0018]
As shown in FIG. 1, the document transport unit 1 has a pickup roller 10 that feeds out the uppermost document S placed on the placement tray 22. The pickup roller 10 is connected to a separation roller 11 that is positioned on the downstream side of the pickup roller 10 and separates the document S by a long connecting plate. Further, pulleys (not shown) are respectively fixed to the roller shafts of the pickup roller 10 and the separation roller 11, and an endless belt (not shown) is stretched between the pulleys. For this reason, the pickup roller 10 is rotatable about the roller shaft of the separation roller 11 by its own weight, and comes into contact with the uppermost document S placed on the placement tray 22 to endlessly from the separation roller 11 side. It is possible to feed out the uppermost document S with the rotational driving force supplied through the belt. A rubber separation pad 16 having a frictional force is in contact with the bottom peripheral surface of the separation roller 11, and the separation pad 16 is biased upward (peripheral surface side of the separation roller 11) by a spring 17. The placement tray 22 is provided with an empty sensor (not shown) for detecting a state in which no document is placed.
[0019]
The document transport unit 1 extends from the loading tray 22 to the sheet discharge tray 3 that is integrally formed with the cover 3a that covers the fixed document platen glass 73 of the image reading unit 2 and has a gently inclined surface on the upper side. A substantially U-shaped conveyance path that allows conveyance of the document S within the installation area is provided.
[0020]
Further, the document transport unit 1 transports the document S toward the reading position Pr (see FIG. 2) at the substantially central portion of the reading platen glass 72 on the upstream and downstream sides with respect to the flowing reading platen glass 72. A discharge roller 14 that receives the document S conveyed by the roller 12 and the conveyance roller 12 and conveys the document S toward the sheet discharge tray 3 is disposed.
[0021]
Between the transport roller 12 and the discharge roller 14, a guide plate 21 is disposed that guides the back surface (the back surface of the image recording surface) of the document S that is curved and transported on both sides. A cueing sensor 80 for detecting the leading edge and the trailing edge of the conveyed document S is fixed to the guide plate 21 in the vicinity of the conveying roller 12 (see FIG. 2).
[0022]
The fixing position of the cue sensor 80 will be described in detail. As shown in FIG. 2, the image sensor 53 is set to a position 400 lines before the reading position Pr for reading the image recording surface of the document S. As described above, since the reading density of the image sensor 53 in the document conveyance direction is 400 dpi, the image sensor 53 is positioned 1 inch (25.4 mm) before the reading position Pr. Actually, since the fixing position varies due to an attachment error or the like, the number of offset lines is finely adjusted by a dip switch (not shown). Therefore, the value of the dip switch is set in the assembling process of the document conveying unit 1, and the number of offset lines is determined.
[0023]
As shown in FIG. 1, the conveyance roller 12 is fixed to the conveyance shaft, and a gear pulley (not shown) is fitted to one side of the conveyance shaft. A gear pulley (not shown) is fitted on the motor shaft of the carry motor 20 that is a drive source of the carry roller 12, and a timing belt is stretched between a gear pulley (not shown) and a gear pulley (not shown). . A stepping motor is used as the conveyance motor 20, and one step is set to correspond to one line of document reading by the image sensor 53. The transport roller 12 is in contact with a transport roller 13 that is driven to rotate by the transport roller 12 and is supported by the shaft with a certain clearance.
[0024]
On the other hand, the discharge roller 14 side has a similar structure. That is, the discharge roller 14 is fixed to the discharge shaft. A timing belt is stretched between a gear pulley (not shown) fitted to the discharge shaft and a gear pulley (not shown) fitted to the motor shaft of the conveyance motor 20. The force is also transmitted to the discharge roller 14. The discharge roller 14 is in contact with a discharge roller 15 that is driven and rotated by the discharge roller 14 and is supported on the shaft with a certain clearance.
[0025]
As shown in FIG. 2, a conveyance measuring unit 30 that monitors the conveyance fluctuation of the document S is fixed to the guide plate 21 at a position upstream of the reading position Pr. The conveyance measurement unit 30 includes a light emitting diode 34, a lens 33 that collects light reflected from the back surface of the document S, an image sensor 32, an operation circuit that operates the image sensor 32, an amplifier that amplifies the output from the image sensor 32, and It has a unit board 31 on which an A / D converter or the like for converting the output from the amplifier is mounted, and these components are integrally fixed to the unit frame 35 in order to suppress the influence of vibration and the like. Yes.
[0026]
In this embodiment, a blue light emitting diode is used to increase the amount of light in the light emitting diode 34, but a laser diode having a higher amount of light may be used. The reflected light emitted from the light emitting diode 34 and reflected by the back surface of the document S is collected by the lens 33 and enters the image sensor 32. The image sensor 32 has two monochrome line sensors that are long in the direction (main scanning direction) intersecting the transport direction (sub-scanning direction) of the document S. The two line sensors are separated from each other by one line or more (in this embodiment, the separation distance is set to 10 lines).
[0027]
Assuming that the position where the illuminance of the light emitting diode 34 is highest is the monitoring position Pw, the monitoring position Pw is set to the center position between the two line sensors constituting the image sensor 32. The reading position Pr and the monitoring position Pw are set at different positions in order to avoid interference by the light emitting diode 34 and the illumination lamp 60 with respect to the image sensors 53 and 32. In the present embodiment, the monitoring position Pw is set 50 lines upstream of the reading position Pr, and one (upstream) line sensor of the image sensors 32 has the cue sensor 80 positioned at the leading edge of the document S. The other (downstream) line sensor is arranged on the 355th line from the position where the cue sensor 80 detects the leading edge of the document S.
[0028]
As shown in FIG. 4, the document transport unit 1 includes a microcomputer 100 that controls the document transport unit 1. The microcomputer 100 is connected to a cueing sensor 80, a driver 101 that drives the conveyance motor 20, and a fluctuation amount detection circuit 38. The driver 101 is connected to the conveyance motor 20, and the fluctuation amount detection circuit 38 is connected to the conveyance measurement unit 30. It is connected. The microcomputer 100 is connected to the image reading unit 2 via the ADF connector 102. In FIG. 4, the stepping motor that drives the separation roller 11 and the pickup roller 10, the driver thereof, the empty sensor disposed on the mounting tray 22, and the like are omitted.
[0029]
The document reading apparatus according to the present embodiment can read a document by placing the document on the fixed document platen glass 73 in the same manner as a known document reading device, and can place the document on the fixed document platen glass 73. As described above, the document conveying unit 1 is configured to be openable and closable (turnable) with respect to the image reading unit 2.
[0030]
(Operation)
Next, the operation in the sheet through mode of the image reading apparatus according to the present embodiment will be described.
[0031]
When the microcomputer 120 receives an instruction to read a document in the sheet-through mode from the external device via the communication IC 126, the microcomputer 120 turns on the illumination lamp 60, activates the image sensor 53, and drives a stepping motor (not shown). The first carriage 50 and the second carriage 51 are moved to the reading position Pr (state shown in FIG. 1). In addition, the microcomputer 120 notifies the microcomputer 100 that there has been a read command.
[0032]
Receiving the reading instruction from the microcomputer 120, the microcomputer 100 determines whether or not a document is placed on the placement tray 22 based on an output from the empty sensor. When it is determined that the document is not placed, the microcomputer 120 is notified of this and waits until the document is placed. The microcomputer 120 notifies the external device via the communication IC 126 that the document should be placed on the placement tray 22.
[0033]
On the other hand, when it is determined that a document is placed on the placement tray 22, the microcomputer 100 activates the conveyance measurement unit 30 and drives the conveyance motor 20 that supplies a rotational driving force to the separation roller 11. . As a result, the document S placed on the uppermost portion of the placement tray 22 is fed by the pickup roller 10 (this time is referred to as “document feeding time” for convenience), and is reduced by the frictional force between the separation roller 11 and the separation pad 16. Separated into sheets. The document S is conveyed downstream by the separation roller 11, nipped by the conveyance roller 12 and the conveyance roller 13, and conveyed further downstream via the reading position Pr.
[0034]
The microcomputer 100 sets the internal counter to 0 when the cue sensor 80 detects the leading edge of the document S, and increments the internal counter by 1 each time the transport motor 20 is rotated by one step (conveys the document S by one line), It is determined whether or not the value of the internal counter is 345, that is, whether or not the leading edge of the document S has been conveyed to the position of the upstream line sensor in the image sensor 32. At the time of determination, the A / D converter of the unit board 31 is operated. The monochrome image information output from the image sensor 32 by the operation of the A / D converter is input to the fluctuation amount detection circuit 38, and the fluctuation amount detection circuit 38 transmits the fluctuation amount to the microcomputer 100 for each line.
[0035]
Here, the relationship between the conveyance measurement unit 30 and the fluctuation amount detection circuit 38 for conveyance monitoring of the document S will be described. As described above, the image sensor 32 has two line sensors on the upstream side and the downstream side, and the two are separated by 10 lines. Therefore, if the document S is conveyed at a constant speed, the image information output from both coincides by correcting the time corresponding to 10 lines, but if the document S is not conveyed at a constant speed (for document conveyance). If there is a change), the image information does not match and the difference (amount of change) should be revealed. For this reason, as shown in FIG. 5, the fluctuation amount detection circuit 38 temporarily stores the image information output from the upstream line sensor for each line, and after the time corresponding to 10 lines has elapsed, from the upstream line sensor. The output image information is compared with the image information output from the downstream line sensor, and the difference between the image information is detected as a fluctuation amount.
[0036]
Further, the microcomputer 100 determines whether or not the fluctuation amount detected by the fluctuation amount detection circuit 38 is equal to or less than a predetermined threshold value (which does not affect the acquisition of image data by the image sensor 53). The amount is regarded as 0, and when the determination is negative, the detected amount of variation is regarded as the amount of variation caused by document conveyance. In FIG. 5, the amount of change when a negative determination is made is shown as behavior information. On the other hand, the microcomputer 100 has position information of the document S in the sub-scanning direction by an internal counter. For example, when the document S is A4 size, the microcomputer 100 determines the value of the internal counter (position information) from the leading edge of the document S where the value of the internal counter is 345 to the rear end of the document S where the value of the internal counter is 5032. The behavior information (variation amount) corresponding to is generated as deviation information and sent to the microcomputer 120. The microcomputer 100 may send all the fluctuation amounts corresponding to the internal counter values 345 to 5032 to the microcomputer 120. However, in this embodiment, the behavior corresponding to the position information is reduced in order to reduce the communication load. Only the information is sent to the microcomputer 120 (when the fluctuation amount is 0, the position information is not sent). The microcomputer 120 sequentially sends the deviation information received from the microcomputer 100 to the image processing IC 125.
[0037]
Further, the microcomputer 100 determines whether or not the value of the internal counter is 400, in other words, whether or not the leading edge of the document S has been transported to the reading position Pr. At the time of determination, the microcomputer 120 is notified of a reading start command. Receiving the reading start command, the microcomputer 120 starts A / D conversion by the A / D converter 122. As a result, the image recording surface of the document S is read by the image sensor 53 of the image reading unit 2. That is, the light emitted from the illumination lamp 60 or through the reflector 64 is reflected by the image recording surface of the document S at the reading position Pr, and the first to third mirrors 61 to 63 through the flow reading platen glass 72. The light path is changed, and the light is collected by the lens unit 52 and enters the image sensor 53. As shown in FIG. 4, the output from the image sensor 53 is sequentially converted by the A / D converter 122 for the pixel rows of the photoelectric conversion elements arranged in a line in the conveying direction of the document S, and image data for one line. Then, after the line is delayed, the shading correction processing unit 123 performs correction for one line for each RGB, and then the image is sent to the image processing IC 125. The image processing IC 125 stores the image data after the shading correction processing in the page memory for each RGB. When the image sensor 53 reads one line, the conveyance of the document S by the conveyance motor 20 is also sent by one step (one line).
[0038]
When the value of the internal counter of the microcomputer 100 is 800, the leading edge of the document S conveyed by the conveying roller 12 is set so as to contact the discharge roller 14 or the discharge roller 15. In addition, when the document S is A4 size, the microcomputer 100 determines that the A of the unit substrate 31 when the value of the internal counter reaches 5032 (when the rear end of the document S is positioned at the downstream line sensor). The A / D conversion by the / D converter is terminated. Further, the microcomputer 100 reads the trailing edge of the document S by the conveyance of the conveyance motor 20 when the internal counter value is further increased by 400 from the time when the cue sensor 80 detects the trailing edge of the document S. The microcomputer 120 notifies the microcomputer 120 of a reading end command on the assumption that the position Pr has been reached. Receiving this reading end command, the microcomputer 120 ends the A / D conversion by the A / D converter 122.
[0039]
Here, with reference to FIG. 5, the color blur detection performed by the image processing IC 125 will be described in detail. The color blur is conspicuous in an achromatic region (monochrome) in the image, and appears in a high-contrast portion such as a lateral edge portion (see FIG. 7A) or a boundary in the image. As shown in FIG. 6A, image data read by an image reading apparatus such as a scanner is classified into a color portion and an achromatic color portion. Both of them have a high contrast portion. A reading error exists in the same manner, but the portion where the color blur is particularly conspicuous is a hatched area shown in FIG. The microcomputer 120 notifies the image processing IC 125 of the position information among the sequentially detected deviation information as color blur candidate position information in parallel with the image data after the shading correction processing being stored in the page memory. In other words, the image processing IC 125 performs (1) CIEL on the image data (RGB-specific data) after the shading correction processing corresponding to the notified color blur candidate position information. ^* a ^* b ^* 6A by performing conversion, (2) detection of an achromatic region (separation between color and monochrome), (2) detection of a high contrast portion in the achromatic region, and (4) detection of color blur. The hatched portion shown in FIG. 3 is detected. The following procedure is executed in detail.
[0040]
(1) First, CIE, which is standardized by CIE and is said to be close to human perceptual chromaticity. ^* a ^* b ^* Convert to color system. That is, for the image data after the shading correction process corresponding to the color blur candidate position information, the color system is converted to the XYZ dye system by the following equation (1), and the L is expressed by the following equation (2). ^* a ^* b ^* Convert to color system. In Equation (2), Xn is 95.045, Yn is 100.000, and Zn is 108.892.
[0041]
[Expression 1]

[0042]
(2) As shown in FIG. ^* a ^* b ^* In the chromaticity diagram of the color system, a ^* Shaft and b ^* The axes are orthogonal, and the orthogonal point is an achromatic point. a ^* Value, b ^* By determining the range of values, an achromatic region can be extracted. When there is no color blur, it is easy to separate color and monochrome (hereinafter referred to as monochrome), but when there is color blur, the characteristics of color and color blur are very similar, and pixels Since it is difficult to separate color and monochrome on a unit basis (it is difficult to separate color and color blur only by color), for example, an achromatic region is detected by the following algorithm.
[0043]
{Circle around (1)} Image data is divided into small areas for each m × m (for example, 8 pixels × 8 pixels) in order to create a cumulative histogram.
(2) In the small area of (1), a in the vertical direction corresponding to the main scanning direction ^* Value and b ^* Create a cumulative histogram of values. However, the accumulated value is normalized by the accumulated number of pixels.
(3) Cumulative value in (2) is Ta _SL <A ^* <Ta _SH And Tb _SL <B ^* <Tb _SH Those that fall within the value range of are detected as achromatic regions.
(4) Only a portion that is not determined as an achromatic region in (3) is a in the horizontal direction corresponding to the sub-scanning direction. ^* Value and b ^* Create a cumulative histogram of values. Again, the accumulated value is normalized by the accumulated number of pixels.
(5) Cumulative value in (4) is Ta _ML <A ^* <Ta _MH And Tb _ML <B ^* <Tb _MH Those within the range of the value of are also detected as achromatic regions.
[0044]
(3) Since color blur occurs in the conveyance direction (sub-scanning direction) of the document S, a high contrast portion in the horizontal direction in the achromatic region using the 3 × 3 vertical Sobel filter shown in FIG. Edge portion) is detected. That is, assuming that the center of the matrix of image data is M (i, j), the center value M (i, j) ′ of the matrix after the Sobel filter processing is M (i, j) ′ = M (i−1). , J−1) × (−1) + M (i, j−1) × (−2) + M (i + 1, j−1) × (−1) + M (i−1, j) × 0 + M (i, j ) × 0 + M (i + 1, j) × 0 + M (i−1, j + 1) × 1 + M (i, j + 1) × 2 + M (i + 1, j + 1) × 1. Therefore, for example, in the image data shown in FIG. 7B, the center value M (i, j) ′ of the left matrix is obtained as 16, and the center value M (i, j) ′ of the right matrix is It is calculated as 0. In the image reading apparatus of the present embodiment, a high contrast portion in the horizontal direction is detected because color blur occurs in the conveyance direction of the document S. However, even if the algorithm is changed in the vertical direction (sub-scanning direction), You may use both together.
[0045]
(4) Color blur occurs in a high contrast portion (edge portion) in the achromatic color region. ^* Value, b ^* Value is Ta _DL <A ^* <Ta _DH Or Tb _DL <B ^* <Tb _DH The pixel is generated in a pixel outside the range, and this pixel can be determined as a color blur pixel, and the position of the color blur pixel can also be specified from the image data. That is, if the pixels around the target pixel (peripheral pixels) in the achromatic color region are in color, the peripheral pixels are detected as color blur. Table 1 below summarizes threshold values used in color blur detection.
[0046]
[Table 1]

[0047]
The microcomputer 120 notifies the image processing IC 125 of the color blur occurrence candidate position as color blur candidate position information to the image processing IC 125, and the image processing IC 125 executes (1) to (4) described above for the color blur candidate position. By doing so, color blur detection is executed.
[0048]
The color blur of the image data is caused by the scanning of the image sensor 53 in the sub-scanning direction is not at a constant speed and the RGB reading is not simultaneous in time. In other words, when the conveyance fluctuation of the document S occurs at a certain time, the RGB image data is affected (part of the image is expanded or contracted). The effect appears. For example, when R extends at an edge portion that changes from white to black, a red portion (color blur) occurs at the edge portion. To correct this, weighed whether the image was stretched or shrunk in the part where the color blur occurred, and the amount of expansion / contraction (the amount of expansion / contraction to be corrected). (Shrink in the sub-scanning direction). If shrunk, the shrunk portion may be stretched (enlarged in the sub-scanning direction).
[0049]
The microcomputer 120 calculates (determines) the amount of expansion / contraction to be corrected from the amount of variation in the deviation information received from the microcomputer 100, and notifies the image processing IC 125 of the position to be corrected and the amount of expansion / contraction to be corrected. The variation amount-expansion / contraction amount table is developed in advance in the RAM of the microcomputer 120, the variation amount corresponding to the position stored in the RAM is read, and the variation amount-expansion / contraction amount table is referred to be corrected. The amount of expansion / contraction may be calculated.
[0050]
Upon receiving this notification, the image processing IC 125 corrects the image data according to the position to be corrected and the amount of expansion / contraction to be corrected notified from the microcomputer 120 for each RGB, and then corrects the separation between the color sensors constituting the image sensor 53. Time difference correction and RGB image processing are performed by superimposing RGB. The image data processed in this way is sent to the external device via the communication IC 126, and reading of the original S for one sheet is completed when the transmission of the image data of the last line is completed. Note that the reading of the document S in the sheet-through mode returns to the above-described document feeding time until the empty sensor detects that there is no document on the loading tray 22 or until a reading stop command is received from the external device. The process continues for the next document placed on the placement tray 22.
[0051]
(Action etc.)
Next, the operation and the like of the image reading apparatus of the present embodiment will be described.
[0052]
In the image reading apparatus according to the present embodiment, the microcomputer 120 grasps deviation information (behavior information corresponding to position information) in the conveyance direction of the document S by the cooperation of the conveyance measurement unit 30 and the microcomputer 100, and includes the deviation information. Since the position information is notified to the image processing IC 125 as color blur candidate position information, the image processing IC 125 does not need to perform color blur detection for all areas of image data for each RGB, and color blur is limited to the notified area. Perform detection. That is, in the present embodiment, when an abnormal conveyance is detected by measuring the conveyance variation of the document S, it is assumed that there is a factor that causes color blur, and the color blur candidate position is assumed. The color blur detection is executed, and if there is a color blur, it is assumed that the color blur position is correct. Therefore, unlike the prior art, it is not necessary for the image processing IC 125 to perform color blur detection for all the pixels of the RGB image data. Therefore, the image reading apparatus of the present embodiment can detect color blur in real time without applying a huge calculation load to the color blur detection.
[0053]
Further, in this embodiment, paying attention to the principle that color blur occurs in the image data of the portion when the conveyance variation of the document S occurs, the microcomputers 100 and 120, the variation detection circuit 38, and the image processing IC 125 cooperate. Accordingly, the color blur of each image data corresponding to the behavior information (variation amount) among the deviation information generated by the variation amount detection circuit 38 corresponding to the color blur position detected by the image processing IC 125 for each RGB image data. Correct. For this reason, unlike the prior art that analyzes only the color image data, the image data in which the color is correctly inserted is not erroneously determined as color bleeding. Therefore, the image reading apparatus according to the present embodiment can correct the color blur of the image data due to the conveyance variation of the document S correctly.
[0054]
Furthermore, in this embodiment, two line sensors that are long in the direction (sub-scanning direction) intersecting the conveyance direction of the document S separated by 10 lines are used for the image sensor 32 of the conveyance measurement unit 30. The fluctuations in transport are monitored without contact. For this reason, it is possible to accurately measure the conveyance variation without affecting the conveyance of the document S. Therefore, the microcomputer 120 can correctly determine the amount of expansion / contraction to be corrected for the color blur of the image data, and as a result, can correct the color blur of the image data by the image processing IC 125 correctly. In other words, the quality of image data sent from the image reading apparatus of the present embodiment to the external apparatus via the communication IC 126 can be improved.
[0055]
In the present embodiment, the active measurement type having the light emitting diode 34 in the transport measurement unit 30 is exemplified. However, as shown in FIG. 3, the passive method lacking the configuration corresponding to the light emitting diode 34 shown in FIG. The transport measurement unit 130 may be used. That is, the conveyance measurement unit 130 includes a lens 133 that collects transmitted light that has passed through the document S, an image sensor 132 that includes two line sensors separated by 10 lines, an operation circuit that operates the image sensor 132, and the image sensor 132. The unit board 131 is mounted with an amplifier for amplifying the output and an A / D converter for converting the output from the amplifier, and these components are mounted on the unit frame 135 to suppress the influence of vibration and the like. It is fixed together. In the transport measurement unit 130, the center between the two line sensors is the monitoring position Pw, and the monitoring position Pw and the reading position Pr coincide with each other. Accordingly, when the upstream and downstream line sensors are separated by 10 lines, they are arranged on the 395th and 405th lines from the position where the cueing sensor 80 detects the leading edge of the document S, respectively. In such a configuration, since the transmitted light is used and the fibers constituting the document S are also included in the image information, the conveyance fluctuation of the document S can be accurately measured. In addition, since a separate light source is not required, there is an advantage that the read image is not affected, and the behavior of the document at the reading position can be detected, so that fluctuations can be detected accurately.
[0056]
Furthermore, in this embodiment, CIEL is used for color blur detection performed by the image processing IC 125. ^* a ^* b ^* Although the conversion method has been exemplified, the present invention is not limited to this. For example, from RGB three primary colors, which pay attention to the fact that the luminance value of at least one color of RGB is greatly different from the luminance value of at least two other colors. A color method based on the colors of colors or a correlation method using color correlation may be used, and even such a color blur detection method may be described as “a color blur existing in a high-contrast portion in an achromatic region of color image data”. Can detect the position. " Details of these color blur detection methods are detailed in Japanese Patent Application No. 2002-089928 filed on February 19, 2002 by the present applicant.
[0057]
Further, in the present embodiment, an example in which the variation amount of the document conveyance is measured based on the difference in the image information by comparing the outputs from the two line sensors is shown, but the present invention is not limited to this, for example, the document The speed of S may be measured, and the speed difference may be used as the fluctuation amount of the document conveyance. In addition, when using the active method as in the present embodiment, laser light is irradiated, or the speed change using the Doppler effect is detected by generating sound including ultrasonic waves, not limited to light. Also good.
[0058]
Furthermore, in the present embodiment, the microcomputers 100 and 120, the variation detection circuit 38, and the image processing IC 125 are described separately. However, the present invention is not limited to this, and for example, these are one microcomputer and one image processing IC. The microcomputer may execute image processing executed by the variation detection circuit 38 and the image processing IC 125. In the present embodiment, an example is shown in which the microcomputers 100 and 120, the variation detection circuit 38, and the image processing IC 125 are operated together. However, the microcomputer 100 and 120 are configured by hardware. Also good.
[0059]
In this embodiment, an example in which the document transport unit 1 and the image reading unit 2 are configured separately is shown. However, if only reading in the sheet-through mode is performed without reading with a fixed document, the document feeding unit 1 and the image reading unit 2 are fixed. The original platen glass 73 is unnecessary, the projected area of the entire original reading apparatus can be made considerably small, and an integrated structure is possible apart from the cancellation of the conveyance failure.
[0060]
【The invention's effect】
As described above, according to the present invention, focusing on the principle that color blur occurs in the color image data at the location when document transport fluctuation occurs, the image data correction unit detects the color blur detection unit. Since the color image data corresponding to the position measured by the measuring means among the blurred color positions is corrected based on the amount of variation measured by the measuring means, it is more accurate than the conventional technique for analyzing only the color image data. It is possible to obtain an effect that the color blur of the color image data can be corrected without erroneously determining the color blur as to the image data in which the color is inserted.
[Brief description of the drawings]
FIG. 1 is a schematic front sectional view of an embodiment of an image reading apparatus to which the present invention is applicable.
FIG. 2 is a front sectional view of the vicinity of a flow reading platen glass of the image reading apparatus according to the embodiment.
FIG. 3 is a front sectional view of the vicinity of a flow reading platen glass of an image reading apparatus according to another embodiment.
FIG. 4 is a schematic block circuit diagram of the image reading apparatus according to the embodiment.
FIG. 5 is an operation explanatory diagram schematically showing an operation related to color blur correction of the image reading apparatus according to the embodiment.
6A is an explanatory diagram schematically showing classification of image data included in a read image read by an image sensor, and FIG. 6B is CIEL. ^* a ^* b ^* It is explanatory drawing which shows typically the relationship between the perceived chromaticity and color in a method.
FIG. 7A shows CIEL. ^* a ^* b ^* FIG. 5B is an explanatory diagram showing a color blur occurrence edge and a vertical direction Sobel filter in the document conveyance direction in the method, and FIG. 9B is an explanatory diagram showing an example of image data.
[Explanation of symbols]
1 Document transport unit (part of image reader)
2 Image reading unit (part of image reading device)
3 Output tray
3a cover
10 Pickup roller (part of transport means)
11 Separation roller (part of transport means)
12 Conveying roller (part of conveying means)
13 Transport roller (part of transport means)
14 Discharge roller (part of transport means)
15 Discharge roller (part of transport means)
16 Separation pad
17 Spring
20 Paper discharge motor
21 Guide plate
22 Loading tray
30 Transport measurement unit (monitoring sensor)
32 Image sensor (monitoring sensor light receiving element)
33 Lens (monitoring sensor)
34 Light-emitting diode (monitoring sensor light-emitting element)
35 frame unit
50 First carriage
51 Second carriage
52 Lens unit
53 Image sensor
54 Analog board
55 Image processing board
56 Interface connector
60 Lighting lamp (light source)
61 First mirror
62 Second mirror
63 Third mirror
64 reflector
70 Document guide (scooping up)
71 Document guide (scooping)
72 Flow-reading platen glass
73 Fixed Document Platen Glass
75 casing
80 Cue sensor (tip detection sensor)
100 Microcomputer (part of measuring means)
101 driver
102 ADF connector
120 microcomputer (part of image data correction means)
122 A / D converter
123 Shading correction processing unit
124 clock generator
125 Image processing IC (color blur detection means, part of image data correction means)
126 Communication IC
128 Scanner connector
130 Transport measurement unit
131 Unit board (monitoring sensor)
132 Image sensor (monitoring sensor photo detector)
133 lens (monitoring sensor)
135 Unit frame (monitoring sensor)
S manuscript
Pr reading position
Pw monitoring position

Claims (9)

Conveying means for conveying an original;
A light source for illuminating the document surface conveyed by the conveying means;
An image sensor for converting light from the document surface into color image data;
A measuring means for measuring a variation amount and a position of the document conveyance by an output from a monitoring sensor for monitoring the document conveyed by the conveyance means;
Color blur detection means for detecting a position of color blur existing in a high contrast portion in an achromatic region of color image data converted by the image sensor;
Image data correction means for correcting color image data corresponding to the position measured by the measurement means among the color blur positions detected by the color blur detection means based on the amount of variation measured by the measurement means;
An image reading apparatus comprising: 2. The monitor sensor according to claim 1, further comprising: a light emitting element that emits light, and a light receiving element that receives reflected light from the back side of the document. The image reading apparatus described. 2. The image reading apparatus according to claim 1, wherein the monitoring sensor includes a light receiving element that is disposed on a back surface opposite to the document surface and receives transmitted light that is emitted from the light source and transmitted through the document. . The monitoring sensor includes transmitting means for transmitting a sound wave or light in accordance with an applied signal, and receiving means for receiving a reflected sound wave or reflected light from a document surface and outputting a received signal. The image reading apparatus according to 1. 5. The measuring unit according to claim 2, wherein the measuring unit measures at least two received light signals or received signals obtained from the light receiving element or the receiving unit at different times to measure the variation amount of the document conveyance. The image reading apparatus according to any one of the above. The measuring means has a leading edge detection sensor for detecting a leading edge in the document conveyance direction, and measures the variation amount of the document conveyance corresponding to position information with reference to the document leading edge detected by the leading edge detection sensor. The image reading apparatus according to claim 1. The measuring means determines whether or not the fluctuation amount of the document conveyance corresponding to the position information exceeds a predetermined amount set in advance, and determines that the position information is the color information when it is determined that the amount exceeds the predetermined amount. The blur detection unit is notified as a candidate position where color blur occurs, and the color blur detection unit is configured to detect a color image data in the achromatic region of the color image data corresponding to the position information notified from the measurement unit of the color image data. The image reading apparatus according to claim 1, wherein a position of a color blur existing in a contrast portion is detected. The image data correction unit corrects the color image data at the color blur position detected by the color blur detection unit when the fluctuation amount of the document conveyance measured by the measurement unit exceeds a predetermined amount set in advance. The image reading apparatus according to claim 1, wherein: The image reading apparatus according to claim 8, wherein the image data correction unit determines the correction amount of the color image data according to a variation amount of document conveyance measured by the measurement unit.

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