JP2004080594A - Image reader - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform the calibration of a magnification for printing an image of the same size as an original image on a film. <P>SOLUTION: After setting a mode to a duplication mode in S1, the operation of magnification calibration is started in S2. A magnification calibration chart image is processed corresponding to a set parameter and transferred to a printer in S3. In S4, the transferred chart image is enlarged to the full printer area width of the printer to be used and the film for the magnification calibration is printed. The film for the magnification calibration is set to an image reader in S5 and the film for the magnification calibration is read in S6. In S7, the image is formed by using a film reading means and a data processing means, an image processing is performed to the image and the width of the print area is calculated. In S8, the value is recorded in a parameter recording means as a read area parameter used in the duplication mode. In S9, after the operations are ended, the image reader is turned to a state capable of reading the film. <P>COPYRIGHT: (C)2004,JPO

Description

【００２１】
パラメータ記憶手段１８は不揮発性メモリやハードディスクドライブ装置等により構成され、パラメータ設定手段１９において設定されたパラメータを記憶し、パラメータ決定手段１６に記録されたパラメータを出力する。パラメータ決定手段１６はモード選択手段１５から出力されたモード情報を基に、適切なパラメータをフィルム読取手段１１、データ処理手段１２、コメント追記手段１３、データ出力手段１４、チャート画像記憶手段１７に出力する。
【００２２】
フィルム読取手段１１はＸ線撮影によって画像が形成されたＸ線フィルムから画像を読み取り、デジタル画像信号を形成する。ここでは、フィルムをハロゲンランプで照明し、その透過光をライン状のＣＣＤを用いて光電変換し、透過光量に対応した電気信号に変換する。勿論、フィルムにレーザービームを照射して、その透過光をフォトマルチプライヤで電気信号に変換する構成であってもよい。
【００２３】
この電気信号はＡ／Ｄ変換器でデジタル画像信号に変換される。この際に用いられるＣＣＤは、例えば７５００画素を有し、フィルムを読み取る際の主走査方向の読取画素ピッチは約５０μｍである。また、副走査方向の読取画素ピッチも５０μｍとなるように、フィルムの搬送速度とＣＣＤの蓄積時間が決定されている。
【００２４】
フィルム読取手段１１で読み取りを行う領域は、ストレージモードとデュープモードによって異なる。ストレージモードでは先の図１３で示すように、フィルムの左右上下各２ｍｍずつのマージンを含む領域を読み取ることにより、フィルム上の全ての画像が画像データとして確実に記録する。
【００２５】
一方、デュープモードでは等倍の画像をプリントするために、使用するプリンタに対して倍率較正を行い、出力するプリンタのプリント領域と一致するような読取領域のみを読み取る。なお、デュープモードにおける倍率較正の方法については後に詳細に説明する。
【００２６】
データ処理手段１２はフィルム読取手段１１で読み取られたデジタル画像信号を、パラメータ決定手段１６に決定されたパラメータに応じて適切にデータを処理する。ここでは、設定された読取画素ピッチとなるように、主走査方向・副走査方向のデータを線形補間により適切な画素サイズに変換する。
【００２７】
また、設定された濃度範囲やビット数になるように、変換テーブルによる変換も行う。この変換テーブルには、パラメータ決定手段１６で決定されたテーブルを用いる。例えば、表１に示すように設定された変換テーブルが濃度リニアである場合は、読み取られた濃度値に対して線形なテーブルでそれぞれの階調数になるように変換する。８ｂｉｔｓの場合は最大値が２５５に、１２ｂｉｔｓの場合は４０９５になるように変換される。
【００２８】
更に、ＪＰＥＧのフォーマットが指定されている場合には、ＪＰＥＧ圧縮による圧縮を行う。フォーマットは他にも、ＤＩＣＯＭフォーマットやＰＧＭフォーマット等があり、これらのフォーマットには読み取った画像データに規定のヘッダを付加する。
【００２９】
コメント追記手段１３はデュープモードの際に複製された画像であることを示すコメントを画像上に追加する。データ出力手段１４はパラメータ決定手段１６に決定されたプリンタや画像データベースサーバに画像を転送する。それぞれの装置がイーサネット（登録商標）で接続されている場合は、通信先アドレスを指定してＤＩＣＯＭ転送やＦＴＰ転送等により、デュープモード時ではプリンタに、ストレージモード時では画像データベースサーバに画像データを転送する。
【００３０】
データ出力手段１４はＤＩＣＯＭのＰｒｉｎｔ　Ｍａｎａｇｅｍｅｎｔ　Ｓｅｒｖｉｃｅ　Ｃｌａｓｓ、つまり診断装置とプリンタを接続し「画像プリント」するデュープモードで用いる機能と、Ｓｔｏｒａｇｅ　Ｓｅｒｖｉｃｅ　Ｃｌａｓｓつまり装置間で画像を「転送」するストレージモードで用いる機能の両方に対応をしている。このため、先の図１０、図１１で示すように、ＤＩＣＯＭ対応のネットワークに接続されている画像データベースサーバや画像出力装置３には、コンピュータ２を介さずに直接転送が可能である。
【００３１】
チャート画像記憶手段１８はハードディスクドライブ装置等から成り、デュープモードで等倍プリントのために行う倍率較正の際に用いる、図２に示すような倍率較正チャート画像２１を記憶しており、例えば１０００×５００の画素数から成るパターンを有している。デュープモードの倍率較正をする際には、この倍率較正チャート画像２１をプリンタに転送して倍率較正用フィルムをプリントし、プリント領域サイズを測定に用いる。
【００３２】
この倍率較正チャート画像２１の縦方向の大きさは横方向と比較して十分に小さいことが望ましい。これはプリント出力する際に、必ず横方向でフィッティングがなされ、プリンタの画像領域幅一杯まで画像が拡大されて、確実にプリント幅が測定できるからるからであり、具体的には縦横比を１対２以上にすることが望ましい。
【００３３】
図３は図１１に示したように画像読取装置１を画像出力装置３に直接、接続して画像を転送し、デュープモードによりフィルムを作成する場合において、フィルムを読み取る前に必要な倍率較正手順のフローチャート図を示している。
【００３４】
先ず、ステップＳ１において、ユーザがモード選択手段１５を介してモードをデュープモードに設定した後に、ステップＳ２において、フィルム読取手段１１に配備された倍率較正開始スイッチを介して倍率較正モードのスタートを指示すると、倍率較正を行うための動作を開始する。ステップＳ３において図２に示すようなチャート画像記録手段１９に記録された倍率較正チャート画像２１は、パラメータ設定手段１７で設定された画素ピッチ、濃度範囲等のパラメータに応じてデータ処理手段１２で処理され、出力先に設定されたプリンタに転送する。
【００３５】
ステップＳ４において、プリンタに転送されたチャート画像は使用するプリンタのプリンタ領域幅一杯まで拡大され、図４に示すような画像を有する倍率較正用フィルム２２がプリント出力される。この出力された画像の幅を計測することにより使用するプリンタのプリント領域幅を知ることができるが、実際にユーザが測定をする必要はない。
【００３６】
次に、ステップＳ５としてユーザは出力された倍率較正用フィルム２２を画像読取装置のサプライトレイにセットした後に、ステップＳ６として制御盤上のディスプレイの指示に従い、フィルム読取ボタンを押すと、画像読取装置はストレージモードと同じ読取領域を用いて倍率較正用フィルムを読み取る。続いてステップＳ７として、フィルム読取手段１１、データ処理手段１２を用いて画像を形成し、その画像に対してエッジ検出等の画像処理を行い、プリンタのプリント領域の幅を算出する。例えば、読み取ったフィルムの極大値を検出することにより、両端部の線の位置を抽出し、その間の画素数を計測するによりプリント領域幅を算出する。
【００３７】
続いてステップＳ８として、この値をデュープモードで用いる読取領域パラメータとしてパラメータ記録手段１７に自動的に記録する。そして、ステップＳ９においてこれらの倍率較正のための動作が終了した後に、画像読取装置はフィルムの読み取りが可能なＲＥＡＤＹ状態となる。
【００３８】
なお上述の動作において、使用するプリンタの光学系の部品誤差等によりプリンタの画像領域が設計値からずれていたとしても、プリンタから出力された倍率較正用フィルム２２にその誤差が反映されているため、画像領域の算出の際には適当に補正される。また同様に、画像読取装置の光学系にも誤差があることが考えられるが、倍率較正用フィルム２２をその光学系で読み取るため、この画像読取装置の光学系の誤差も適当に補正することができ、結果として、常にオリジナルフィルムの画像と正確に、同じ倍率の画像をプリントすることができる。
【００３９】
次に、デュープモードでフィルムを読み取る際の動作について説明する。図５に示すようなＸ線フィルムをフィルム読取手段１１のトレイにセットし、フィルム読取手段１１に配備されたスイッチ等により、Ｘ線フィルムの読取開始を指示すると、フィルム読取手段１１に画素ピッチや濃度範囲等のパラメータと共に、上述の倍率較正動作で得られたプリント領域幅の値が出力される。
【００４０】
例えば、上述の倍率較正動作で求められたプリント幅が３３４ｍｍであり、フィルム読取手段１１の読取画素ピッチが５０μｍである場合に、横方向６６８０画素が読取領域パラメータとしてフィルム読取手段１１に出力されることとなる。読取領域の高さつまり縦方向の長さについては、プリントされる際の倍率が常に横方向で規定されるように、プリント領域よりも常に小さくなるような一定の値、例えば４１０ｍｍが設定されているので、縦方向８２００画素が読取領域パラメータとしてフィルム読取手段１１に出力される。
【００４１】
フィルム読取手段１１はパラメータ決定手段１６から出力されたこれらのパラメータに応じた読み取り条件で、フィルムの読み取りを行う。この例では、オリジナルフィルム上の横３３４ｍｍ、縦４１０ｍｍ（５０μｍのピッチで６６８０×８２００画素）の領域について、読み取って電子化し画像データを生成する。
【００４２】
続いて、この画像データはパラメータ設定手段１９により指定された画素ピッチとなるように、データ処理手段１２において保管処理が施される。例えば、画素ピッチが２００μｍに設定されている場合には、１６７０×２０５０画素の画像が生成されることとなる。その後に、コメント追記手段１３によりフィルムが複製したものであることを示すコメントを画像に追加し、データ出力手段１４にて指定のプリンタに画像データを転送する。
【００４３】
図６はプリンタで出力したデュープフィルムを示しており、プリンタに転送された画像データはプリンタの画像領域と一致しているため、オリジナルフィルムの画像と同じ大きさの画像をデュープフィルム上に得ることができる。
【００４４】
ここで、プリンタが描画する画素ピッチは、必ずしも画像読取装置が読み取る画素ピッチと一致していなくともよい。転送されてきた画像データに対して、プリンタ側でフィッティングを行うように設定すると、縦、横の何れかの画像領域が一杯になるように拡大・縮小されるため、結果としてデュープフィルム上に得られる画像の大きさは、プリンタの描画画素ピッチ、画像読取装置の読取画素ピッチによらず、オリジナルフィルムの画像と同じ大きさになり、診断に好適なデュープフィルムを得ることができる。画像読取装置はプリンタと直接接続されており、介在するＰＣによる操作をすることなく、容易にデュープフィルム作成を行うことが可能となる。
【００４５】
この第１の実施の形態では、読取領域の高さはプリンタによらず一定の値を用いていたが、図７に示す第２の実施の形態においては、プリント領域高さ測定用の倍率較正チャート画像２３を用いて読取領域の高さを決定することもできる。即ち、ユーザがモード選択手段１５でモードをデュープモードに設定し、フィルム読取手段１１に配備された倍率較正開始スイッチにより倍率較正の開始を指示すると、チャート画像記録手段１９に記録された図２、図４に示すような倍率較正チャート画像をプリンタに転送し、プリント領域幅用、プリント領域高さ用の２枚の倍率較正フィルムが出力される。これを画像読取装置の指示に従って順次に読み取り、プリント領域幅、プリント領域高さをそれぞれ算出し、これに等しい長さの読取領域幅と読取領域高さが、読取領域パラメータとしてフィルム読取手段１１に出力されることとなる。
【００４６】
図８は第３の実施の形態のフローチャート図を示しており、第１、第２の実施の形態においては、プリント領域幅の算出は出力した倍率較正用のフィルムを、画像読取装置で読み込み自動的に行う構成になっていたが、必ずしも自動的に行う必要はない。ステップＳ１４で倍率較正用のフィルムをプリントした後に、ステップＳ１５においてユーザが物差し等でプリント領域を測定し、ステップＳ１６で画像読取装置のパラメータ設定手段１６から、プリントパラメータとして入力することもできる。
【００４７】
図９は第４の実施の形態の構成図を示しており、第１〜３の実施の形態において、画像読取装置は図１０で示すようなパーソナルコンピュータの介在が必要のない装置を用いていたが、図９に示すように画像読取装置３１は、画像読取部３２と制御用パーソナルコンピュータ３３を有し、コンピュータ３２からＳＣＳＩ等のインターフェースを介して制御する型式としても、同様のことを行うことがきる。
【００４８】
この場合には、パーソナルコンピュータ３３に倍率較正用の画像データが記録されており、倍率較正用のアプリケーションをパーソナルコンピュータ３３上の制御用アプリケーションにより行う。以下、第１の実施の形態と同様の作業により簡単な作業で等倍の画像を有するデュープフィルムをプリンタ３４を介して作成することができる。
【００４９】
【発明の効果】
以上説明したように本発明に係る画像読取装置は、簡単な操作でオリジナル画像と同じ大きさの画像を有するデュープフィルムをプリントすることができる。また、画像読取装置やプリンタの光学系による倍率の誤差があったとしても適性に補正されるため常に正しく等倍率のデュープフィルムを得ることができる。
【図面の簡単な説明】
【図１】第１の実施の形態の画像読取装置のブロック回路構成図である。
【図２】第１の実施の形態の画像読取装置の倍率較正チャート画像の正面図である。
【図３】倍率較正手順のフローチャート図である。
【図４】倍率較正用フィルムの正面図である。
【図５】画像読取装置で読み取るＸ線フィルムの正面図である。
【図６】プリンタに接続して出力したデュープフィルムの正面図である。
【図７】第２の実施の形態における倍率較正チャート画像の正面図である。
【図８】第３の実施の形態の動作のフローチャート図である。
【図９】第４の実施の形態における画像読取装置の構成図である。
【図１０】従来例の画像読取装置をコンピュータを介して画像出力装置に接続したシステム構成図である。
【図１１】従来例の画像読取装置を画像出力装置に直接接続したシステムの構成図である。
【図１２】従来例の画像読取装置で読み取るＸ線フィルム画像の説明図である。
【図１３】従来例のＸ線フィルム画像を画像読取装置で読取時の読取領域の説明図である。
【図１４】従来例のプリンタの描画領域の説明図である。
【図１５】従来例の画像読取装置の出力画像をプリンタで出力したフィルムの説明図である。
【符号の説明】
１１　フィルム読取手段
１２　データ処理手段
１３　コメント追記手段
１４　データ出力手段
１５　モード選択手段
１６　パラメータ決定手段
１７　チャート画像記憶手段
１８　パラメータ記憶手段
１９　パラメータ設定手段
２１、２３　倍率較正チャート画像
２２　倍率校正用フィルム[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image reading apparatus that reads an image from an X-ray film on which an image is formed to form a digital image signal, and more specifically, transfers the read digital image signal to an image output device such as a laser imager and outputs the digital image signal. The present invention relates to an image reading apparatus having a function of performing duplication.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, duplication of a medical film such as an X-ray photograph, CT, and MRI is performed by bringing the duplication film into close contact with the medical film of the duplication source and exposing the duplication film with a light source such as UV.
[0003]
At present, when digital medical equipment has become widespread, an image formed on a film is read by an image reading device 1 as shown in FIG. 10, a read digital image signal is sent to a computer 2, and an appropriate process is carried out. The data is transferred to the image output device 3 such as an imager, and is copied in the storage mode.
[0004]
More recently, as shown in FIG. 11, an image reading apparatus 1 capable of directly transferring an image read from a film by an image reading apparatus 1 to an image output apparatus 3 without using a computer 2 to obtain a duplicate film has been developed. Used. The method using the duplication mode has an advantage that the operation is simple because the duplication film can be created without using the computer 2.
[0005]
However, when creating a duplicate film by the method of FIG. 11, if the read image area of the image reading apparatus 1 and the drawing image area of the image output apparatus 3 are different, the sizes of the original film and the duplicate film will be different. Will be. For example, in taking a chest photograph, a half-cut (354 × 430 mm) film as shown in FIG. 12 is generally used. When the image is read by the image reading apparatus 1, the image reading range is larger than the film size because margins are included on the left, right, top and bottom.
[0006]
For example, when the top, bottom, left, and right margins are each 2 mm, the size of the image reading range is 358 × 434 mm as shown in FIG. On the other hand, when the printer outputs a half-cut film (354 × 430 mm) of the same size, the image drawing area is smaller than the film because there are areas where images cannot be drawn on the left, right, top and bottom. For example, as shown in FIG. 14, when there are 10 mm left and right and up and down in each of the areas where the image cannot be drawn, the image drawing area is 334 × 410 mm.
[0007]
When an image read by the image reading device 1 is output by a printer, fitting can be performed until one of the image drawing area of the printer becomes full in the vertical and horizontal directions. However, the image is transferred to the printer by the image reading device as described above. The 358 × 434 mm image is printed out as a slightly reduced image as shown in FIG. That is, since the image reading area read by the image reading apparatus 1 does not match the image drawing area of the printer, an image of a different size from the original image is printed.
[0008]
When the diagnosis is performed using the dupe film created in this way, since the size is different from that of the original image, correct diagnosis may not be performed. For example, when a doctor performing image diagnosis measures the length of a certain part, there is a risk that a value different from the length on the original film may be measured.
[0009]
In order to solve this, the applicants set the print area of the printer to be used in the image reading apparatus in advance and make the area to be read by the scanner equal to the print area, so that an image of the same size can be duplicated. A possible image reading device is proposed.
[0010]
[Problems to be solved by the invention]
However, in the above-described conventional example, it is necessary to inquire the print area of the printer to be used to the printer maker or the like, or to measure the print area of the film to be actually printed, and to input it to the image reading apparatus, which is extremely troublesome. It is.
[0011]
Also, when measuring the magnification error of the optical system of the printer, the magnification error of the optical system of the film scanner, or the print area, due to various factors such as the measurement error, the image to be copied is the image of the original film. May not be exactly the same size.
[0012]
SUMMARY OF THE INVENTION It is an object of the present invention to provide an image reading apparatus which can solve the above-mentioned problems and can easily print an image of the same size as an image on an original film on a duplicate film.
[0013]
[Means for Solving the Problems]
An image reading apparatus according to the present invention for achieving the above object reads an image recorded on a sheet-like medium and directly outputs digital image data to a printer. Means for transferring and outputting the film, means for reading the film, means for calculating the image area of the printer based on the read image, determining a reading area based on the image area of the printer, and output by the printer Means for calibrating the magnification of the image on the film.
[0014]
Further, an image reading apparatus according to the present invention is an image reading apparatus that reads an image recorded on a sheet-like medium and directly outputs digital image data to a printer. Means for outputting and inputting a part of the length of the image on the film measured by the user as a value corresponding to a printer image area; means for determining a reading area based on the input printer image area; Means for calibrating the magnification of the image on the film output by the printer.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
The present invention will be described in detail based on the embodiments shown in FIGS.
FIG. 1 shows a block diagram of the image reading apparatus according to the first embodiment. This image reading apparatus sends digital image data read as shown in FIG. 10 to an image database such as HIS or PACS. And the like, and a duplication mode for sending digital image data to an image output device such as a laser printer as shown in FIG.
[0016]
When using the storage mode or the duplication mode, the image reading apparatus has storage means for holding parameters such as a read pixel pitch, a read density range, and an IP address of an image database server or an image output apparatus for each mode. When one of the modes is set, the reading device can be operated based on the parameters.
[0017]
The output of the film reading means 11 is sequentially connected to a data processing means 12, a comment adding means 13, and a data output means 14. On the other hand, the output of the mode selecting means 15 is connected to the parameter determining means 16, and the output of the parameter determining means 16 is the film reading means 11, the data processing means 12, the comment adding means 13, the data output means 14, the chart image storing means 17 Connected to each. The output of the chart image storage unit 17 is connected to the data processing unit 12. Further, the parameter determination means 16 is connected to the parameter storage means 18, and the output of the parameter setting means 19 is connected to the parameter storage means 18.
[0018]
The mode selection means 15 includes a general storage mode for transmitting digital image data read by an operator to an image database such as HIS or PACS, and a duplication mode for transmitting digital image data to an image output device such as a laser printer. Is selected, and the selected mode information is output to the parameter determining means 16.
[0019]
The parameter setting means 19 sets parameters used in the storage mode or the duplication mode. The parameters to be set are, for example, those relating to image reading parameters in each mode as shown in Table 1 below, such as a density range, a pixel pitch, the number of gradations, a conversion table, a format, and an IP address of an image transfer destination. .
[0020]

[0021]
The parameter storage unit 18 is configured by a nonvolatile memory, a hard disk drive, or the like, stores the parameters set by the parameter setting unit 19, and outputs the parameters recorded in the parameter determination unit 16. The parameter determining means 16 outputs appropriate parameters to the film reading means 11, the data processing means 12, the comment adding means 13, the data output means 14, and the chart image storing means 17 based on the mode information output from the mode selecting means 15. I do.
[0022]
The film reading means 11 reads an image from an X-ray film on which an image has been formed by X-ray photography, and forms a digital image signal. Here, the film is illuminated with a halogen lamp, and the transmitted light is photoelectrically converted using a linear CCD, and is converted into an electric signal corresponding to the amount of transmitted light. Of course, the film may be irradiated with a laser beam, and the transmitted light may be converted into an electric signal by a photomultiplier.
[0023]
This electric signal is converted into a digital image signal by an A / D converter. The CCD used at this time has, for example, 7,500 pixels, and the read pixel pitch in the main scanning direction when reading a film is about 50 μm. The film transport speed and the CCD accumulation time are determined so that the read pixel pitch in the sub-scanning direction is also 50 μm.
[0024]
The area to be read by the film reading means 11 differs depending on the storage mode and the duplication mode. In the storage mode, as shown in FIG. 13, by reading an area including a margin of 2 mm each on the left, right, top and bottom of the film, all the images on the film are reliably recorded as image data.
[0025]
On the other hand, in the duplication mode, in order to print an image at the same magnification, magnification calibration is performed on a printer to be used, and only a reading area that matches a print area of the output printer is read. Note that the magnification calibration method in the duplicate mode will be described later in detail.
[0026]
The data processing unit 12 appropriately processes the digital image signal read by the film reading unit 11 in accordance with the parameters determined by the parameter determining unit 16. Here, the data in the main scanning direction and the sub-scanning direction is converted to an appropriate pixel size by linear interpolation so that the read pixel pitch is set.
[0027]
Further, conversion is performed by a conversion table so that the set density range and the number of bits are set. The table determined by the parameter determining means 16 is used as the conversion table. For example, when the conversion table set as shown in Table 1 is linear in density, the read density value is converted into a linear table with each gradation number. In the case of 8 bits, the maximum value is converted to 255, and in the case of 12 bits, the maximum value is converted to 4095.
[0028]
Further, when the JPEG format is designated, compression by JPEG compression is performed. Other formats include a DICOM format, a PGM format, and the like. In these formats, a specified header is added to read image data.
[0029]
The comment adding means 13 adds a comment indicating that the image is a duplicated image in the duplication mode to the image. The data output unit 14 transfers the image to the printer or image database server determined by the parameter determination unit 16. When each device is connected via Ethernet (registered trademark), the image data is transmitted to the printer in the duplex mode and to the image database server in the storage mode by DICOM transfer or FTP transfer by designating the communication destination address. Forward.
[0030]
The data output means 14 is a function used in DICOM's Print Management Service Class, that is, a function used in a duplex mode in which a diagnostic apparatus is connected to a printer and "image printing" is performed, and a function used in a storage service class in which a image is "transferred" between apparatuses. We have to deal with both. Therefore, as shown in FIGS. 10 and 11, the image data can be directly transferred to the image database server or the image output device 3 connected to the DICOM-compatible network without using the computer 2.
[0031]
The chart image storage means 18 is composed of a hard disk drive or the like, and stores a magnification calibration chart image 21 as shown in FIG. 2 which is used for magnification calibration performed for the same magnification printing in the duplication mode. It has a pattern consisting of 500 pixels. When performing magnification calibration in the duplex mode, the magnification calibration chart image 21 is transferred to a printer to print a magnification calibration film, and the print area size is used for measurement.
[0032]
It is desirable that the vertical size of the magnification calibration chart image 21 be sufficiently smaller than the horizontal direction. This is because fitting is always performed in the horizontal direction when printing, and the image is enlarged to the full width of the image area of the printer so that the print width can be measured without fail. It is desirable that the number be two or more.
[0033]
FIG. 3 shows a magnification calibration procedure necessary before reading the film in the case where the image reading apparatus 1 is directly connected to the image output apparatus 3 to transfer an image as shown in FIG. FIG.
[0034]
First, in step S1, the user sets the mode to the duplication mode via the mode selection means 15, and then in step S2, instructs the start of the magnification calibration mode via the magnification calibration start switch provided in the film reading means 11. Then, an operation for performing magnification calibration is started. The magnification calibration chart image 21 recorded in the chart image recording unit 19 as shown in FIG. 2 in step S3 is processed by the data processing unit 12 in accordance with parameters such as the pixel pitch and the density range set by the parameter setting unit 17. Is transferred to the printer set as the output destination.
[0035]
In step S4, the chart image transferred to the printer is enlarged to the full printer area width of the printer to be used, and the magnification calibration film 22 having an image as shown in FIG. 4 is printed out. By measuring the width of the output image, the print area width of the printer used can be known, but the user does not need to actually measure.
[0036]
Next, after the user sets the output magnification calibration film 22 on the supply tray of the image reading device in step S5, and presses a film reading button in accordance with an instruction on a display on a control panel in step S6, the image reading device Reads the magnification calibration film using the same reading area as in the storage mode. Subsequently, in step S7, an image is formed by using the film reading unit 11 and the data processing unit 12, and image processing such as edge detection is performed on the image to calculate the width of the print area of the printer. For example, by detecting the local maximum value of the read film, the positions of the lines at both ends are extracted, and the print area width is calculated by measuring the number of pixels therebetween.
[0037]
Subsequently, in step S8, this value is automatically recorded in the parameter recording means 17 as a reading area parameter used in the duplication mode. After the operation for calibrating the magnification is completed in step S9, the image reading device enters a READY state in which the film can be read.
[0038]
In the above-described operation, even if the image area of the printer deviates from the design value due to a component error of the optical system of the printer to be used, the error is reflected in the magnification calibration film 22 output from the printer. , Is appropriately corrected when calculating the image area. Similarly, it is conceivable that there is an error in the optical system of the image reading apparatus. However, since the magnification calibration film 22 is read by the optical system, it is necessary to appropriately correct the error of the optical system of the image reading apparatus. As a result, an image of the same magnification can always be printed exactly as the image of the original film.
[0039]
Next, the operation when reading a film in the duplication mode will be described. When an X-ray film as shown in FIG. 5 is set on the tray of the film reading means 11 and an instruction to start reading the X-ray film is given by a switch or the like provided on the film reading means 11, the pixel pitch or the pixel pitch is given to the film reading means 11. The value of the print area width obtained by the above-described magnification calibration operation is output together with the parameters such as the density range.
[0040]
For example, when the print width obtained by the above-mentioned magnification calibration operation is 334 mm and the read pixel pitch of the film reading unit 11 is 50 μm, 6680 pixels in the horizontal direction are output to the film reading unit 11 as a reading area parameter. It will be. For the height of the reading area, that is, the length in the vertical direction, a constant value, for example, 410 mm, which is always smaller than the printing area is set so that the magnification at the time of printing is always defined in the horizontal direction. Therefore, 8200 pixels in the vertical direction are output to the film reading means 11 as a reading area parameter.
[0041]
The film reading means 11 reads a film under reading conditions corresponding to these parameters output from the parameter determining means 16. In this example, an area of 334 mm wide and 410 mm long (6680 × 8200 pixels at a pitch of 50 μm) on the original film is read and digitized to generate image data.
[0042]
Subsequently, the image data is stored in the data processing unit 12 so as to have the pixel pitch specified by the parameter setting unit 19. For example, when the pixel pitch is set to 200 μm, an image of 1670 × 2050 pixels is generated. Thereafter, a comment indicating that the film is a copy is added to the image by the comment adding means 13 and the image data is transferred to the designated printer by the data output means 14.
[0043]
FIG. 6 shows a duplicated film output by a printer. Since the image data transferred to the printer matches the image area of the printer, an image of the same size as the original film can be obtained on the duplicated film. Can be.
[0044]
Here, the pixel pitch drawn by the printer does not necessarily have to match the pixel pitch read by the image reading device. If fitting is performed on the transferred image data on the printer side, the image is enlarged or reduced so that either the vertical or horizontal image area becomes full. The size of the image to be obtained is the same as the image of the original film regardless of the drawing pixel pitch of the printer and the reading pixel pitch of the image reading device, and a dupe film suitable for diagnosis can be obtained. The image reading device is directly connected to the printer, so that it is possible to easily create a duplicate film without performing an operation using an intervening PC.
[0045]
In the first embodiment, the height of the reading area uses a constant value regardless of the printer. However, in the second embodiment shown in FIG. 7, a magnification calibration for measuring the height of the printing area is performed. The height of the reading area can also be determined using the chart image 23. That is, when the user sets the mode to the duplication mode by the mode selection unit 15 and instructs the start of the magnification calibration by the magnification calibration start switch provided in the film reading unit 11, FIG. The magnification calibration chart image as shown in FIG. 4 is transferred to the printer, and two magnification calibration films for the print area width and the print area height are output. These are sequentially read in accordance with the instruction of the image reading apparatus, and the print area width and the print area height are respectively calculated. The read area width and the read area height having the same length are sent to the film reading means 11 as read area parameters. Will be output.
[0046]
FIG. 8 is a flowchart of the third embodiment. In the first and second embodiments, the calculation of the print area width is performed by reading the output magnification calibration film by an image reading device and automatically calculating the print area width. Although the configuration has been performed automatically, it is not always necessary to perform the configuration automatically. After printing the magnification calibration film in step S14, the user can measure the print area with a ruler or the like in step S15, and input the print area from the parameter setting means 16 of the image reading apparatus in step S16.
[0047]
FIG. 9 shows a configuration diagram of the fourth embodiment. In the first to third embodiments, the image reading apparatus uses an apparatus which does not require the intervention of a personal computer as shown in FIG. However, as shown in FIG. 9, the image reading device 31 has an image reading unit 32 and a control personal computer 33, and performs the same thing as a model controlled from the computer 32 via an interface such as SCSI. Cut off.
[0048]
In this case, the magnification calibration image data is recorded on the personal computer 33, and the magnification calibration application is performed by the control application on the personal computer 33. Hereinafter, the duplication film having the same size image can be created via the printer 34 by a simple operation by the same operation as in the first embodiment.
[0049]
【The invention's effect】
As described above, the image reading apparatus according to the present invention can print a duplicate film having an image of the same size as the original image by a simple operation. Further, even if there is an error in magnification due to the optical system of the image reading device or the printer, it is appropriately corrected, so that a duplicating film having the same magnification can always be obtained correctly.
[Brief description of the drawings]
FIG. 1 is a block circuit configuration diagram of an image reading apparatus according to a first embodiment.
FIG. 2 is a front view of a magnification calibration chart image of the image reading apparatus according to the first embodiment.
FIG. 3 is a flowchart of a magnification calibration procedure.
FIG. 4 is a front view of a magnification calibration film.
FIG. 5 is a front view of the X-ray film read by the image reading device.
FIG. 6 is a front view of a duplicate film output by being connected to a printer.
FIG. 7 is a front view of a magnification calibration chart image according to the second embodiment.
FIG. 8 is a flowchart of an operation according to the third embodiment.
FIG. 9 is a configuration diagram of an image reading device according to a fourth embodiment.
FIG. 10 is a system configuration diagram in which a conventional image reading device is connected to an image output device via a computer.
FIG. 11 is a configuration diagram of a system in which a conventional image reading device is directly connected to an image output device.
FIG. 12 is an explanatory diagram of an X-ray film image read by a conventional image reading apparatus.
FIG. 13 is an explanatory diagram of a reading area when an X-ray film image of a conventional example is read by an image reading apparatus.
FIG. 14 is an explanatory diagram of a drawing area of a conventional printer.
FIG. 15 is an explanatory diagram of a film in which an output image of a conventional image reading device is output by a printer.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 11 Film reading means 12 Data processing means 13 Comment adding means 14 Data output means 15 Mode selecting means 16 Parameter determining means 17 Chart image storing means 18 Parameter storing means 19 Parameter setting means 21 and 23 Magnification calibration chart image 22 Magnification calibration film

Claims (8)

In an image reading apparatus which reads an image recorded on a sheet-like medium and directly outputs digital image data to a printer, means for transferring a magnification calibration image to the printer to output a film, reading the film, and reading means. Means for calculating an image area of the printer based on the read image, and means for determining a reading area based on the image area of the printer and calibrating a magnification of the image on the film output by the printer. An image reading apparatus, comprising: 2. The image reading apparatus according to claim 1, wherein the image area of the printer is an image area width of the printer. In an image reading device that reads an image recorded on a sheet-like medium and directly outputs digital image data to a printer, an image for calibration calibration is transferred to the printer, a film is output, and the image on the film measured by a user is output. Means for inputting a part of the length as a value corresponding to a printer image area; means for determining a reading area based on the input printer image area; and Means for calibrating the magnification. The image processing apparatus according to claim 1, further comprising a unit configured to perform magnification calibration so that an image on the film output from the printer has the same size as an image on an original film. The image reading device according to claim 1. The image reading device according to claim 1, wherein an aspect ratio of the number of pixels of the magnification calibration image is any one of 2 or more and 以下 or less. 6. Transferring the two images for magnification calibration, outputting two films, reading the two films, and calculating an image area width and an image area height of the printer based on the read images; The image reading apparatus according to any one of claims 1 to 5, wherein The image reading apparatus according to claim 1, further comprising a unit configured to store the magnification calibration image. The image reading apparatus according to any one of claims 1 to 7, wherein the sheet-shaped medium is an X-ray film.

Images