JP3898875B2 - Electronic endoscope system including an electronic endoscope switching device - Google Patents

Description

【００３３】
表１に示すように、４種類ある面順次方式の第１プロセッサ４０と４種類ある同時単板式の第２プロセッサ６０を、それぞれ「装置１」〜「装置８」とする。本実施形態では、電子内視鏡システムをセッティングする際、切替装置２００に接続される第１および第２プロセッサ４０、６０の種類がプロセッサタイプ設定スイッチ２４０において設定される。例えば、第１プロセッサとして「装置３」が切替装置２００に接続され、第２プロセッサとして「装置７」が切替装置２００に接続される場合、スイッチＳＷ１、ＳＷ２、ＳＷ３、ＳＷ４の開閉状態は、それぞれ順番に、「開」、「閉」、「開」、「閉」となる。なお、先に示した図１では、「装置１」である第１プロセッサ４０が、「装置５」である第２プロセッサが、それぞれ切替装置２００に接続されている。
【００３４】
通常、撮像方式の違いによってプロセッサの処理システムが異なっており、プロセッサを操作するキーボードの入力操作も撮像方式によって異なる。例えば、面順次方式の第１プロセッサ４０では、ファンクションキーのＦ１キーが操作されると画像輪郭処理が施されるように入力操作が定められているが、同時単板式の第２プロセッサ６０では、Ｆ１キーの操作によって画像の拡大処理が実行される。さらに、同じ撮像方式のプロセッサにおいても、種類が異なる場合にはキーボードの入力操作が異なる。ただし、プロセッサの種類とは、製造時の違いによって分類される。そして、本実施形態では、切替装置２００に接続されている第１および第２プロセッサ６０の種類を、プロセッサタイプ設定スイッチ２４０に対する操作によって切替装置２００に登録する。
【００３５】
図４は、キーボードインジケータ切替回路２２６を示した図である。
【００３６】
画像切替設定回路２２４（図２参照）から送られてくるプロセッサ切替信号ＳＳＷＳおよびプロセッサタイプ設定スイッチ２４０の各スイッチＳＷ１〜ＳＷ４から出力されるスイッチ信号は、キーボードインジケータ切替回路２２６の入力ｉｎ０、ｉｎ１、ｉｎ２、ｉｎ３、ｉｎ４にそれぞれ入力される。これら入力される信号に基づき、キーボードインジケータ切替回路２２６では、キーボードインジケータ信号ＫＩＳが内蔵されたキーボード情報メモリ（図示せず）から出力される。
【００３７】
入力ｉｎ１〜ｉｎ４は電圧Ｖｃｃに接続されており、スイッチＳＷ１〜ＳＷ４は閉成時に入力ｉｎ１〜ｉｎ４を接地する。すなわち、スイッチＳＷ１〜ＳＷ４は、閉成時にローレベルの信号「０」を、開放時にハイレベルの信号「１」を入力ｉｎ１〜ｉｎ４へ送る。また、画像切替設定回路２２４から入力ｉｎ０へ送られるプロセッサ切替信号ＳＳＷＳは、第１プロセッサ４０が選択されている場合、ハイレベルの信号「１」となり、第２プロセッサ６０が選択されている場合、ローレベルの信号「０」となる。
【００３８】
例えば、「装置３」である第１プロセッサ４０と「装置７」である第２プロセッサ６０とが切替装置２００に接続され、「装置３」の第１プロセッサ４０が切替装置２００によって選択されている場合（第１プロセッサから出力される映像信号がモニタ１５０等へ送られている場合）、入力ｉｎ０〜ｉｎ４に入力される信号のレベルは、それぞれ順番に、「１」、「１」、「０」、「１」、「０」である。
【００３９】
キーボードインジケータ切替回路２２６では、入力ｉｎ０に入力されるプロセッサ切替信号ＳＳＷＳのレベルに従って、入力ｉｎ１、ｉｎ２、もしくはｉｎ３、ｉｎ４に入力される信号のレベルが判断される。そして、入力ｉｎ１、ｉｎ２、もしくはｉｎ３、ｉｎ４に入力される信号のレベルに基づいて、キーボードインジケータ信号ＫＩＳがキーボード１７０へ送られる。例えば、「装置１」である第１プロセッサ４０と「装置５」である第２プロセッサ６０とが切替装置２００に接続され、「装置１」の第１プロセッサ４０が切替装置２００によって選択されている場合、プロセッサ切替信号ＳＳＷＳのレベルが「１」であることから、スイッチＳＷ１、ＳＷ２から送られてくる信号のレベル（それぞれ「１」、「０」）に基づいて「装置１」に応じたキーボードインジケータ信号ＫＩＳが出力される。このとき、入力ｉｎ３、ｉｎ４に入力される信号のレベルは無視される。
【００４０】
図５は、キーボード１７０に設けられたインジケータ３００の構成を示した図である。
【００４１】
インジケータ３００は、４種類ずつ用意される第１および第２プロセッサ４０、６０に対応させるため、８個の発光ダイオードＬＥＤ１〜ＬＥＤ８を備えたディスプレイ３１０を有するとともに、各発光ダイオードを駆動するキーボードインジケータドライバ３２０を有する。キーボードインジケータドライバ３２０には、キーボードインジケータ切替回路２２６から出力されるキーボードインジケータ信号ＫＩＳが入力される。そして、表２に示すように、キーボードインジケータドライバ３２０は、キーボードインジケータ信号ＫＩＳに基づいて、いずれか１個の発光ダイオードを発光させる。表２においては、８個の発光ダイオードに対応させるため、キーボードインジケータ信号ＫＩＳをＥ１〜Ｅ８と表現している。
【００４２】
【表２】

【００４３】
例えば、「装置１」の第１プロセッサ４０と「装置５」の第２プロセッサ６０が切替装置２００に接続され、「装置１」の第１プロセッサ４０が切替装置２００によって選択されている場合、「Ｅ１」の信号がキーボードインジケータドライバ３２０へ送られる。
【００４４】
図６は、キーボード１７０の外観を示す平面図である。
【００４５】
キーボード１７０には、キーボード信号入出力のための信号ケーブル１７２と、キーボードインジケータ信号ＫＩＳを入力するための信号ケーブル１７４が接続され、信号の送受信が実行される。
【００４６】
インジケータ３００には、表１、表２に示した第１および第２プロセッサ４０、６０の種類の表示に対応して、「装置１」、「装置２」、「装置３」、「装置４」、「装置５」、「装置６」、「装置７」、「装置８」の表示が記されており、発光ダイオードＬＥＤ１〜ＬＥＤ８の配置は、これら「装置１」〜「装置８」の文字表示に対応している。切替装置２００によって選択されたプロセッサに種類の文字表示は、対応する発光ダイオードが点灯することによって照らされる。
【００４７】
例えば、「装置１」の第１プロセッサ４０と「装置５」の第２プロセッサ６０が切替装置に接続されている場合、「装置１」の第１プロセッサ４０が切替装置２００によって選択されていれば「装置１」の文字がダイオードＬＥ１の点灯によって照らされ、一方、「装置５」の第２プロセッサ４０が切替装置２００によって選択されていれば「装置５」の文字がダイオードＬＥ５の点灯により照らされる。
【００４８】
図７は、切替回路２１０の詳細を示した図である。
【００４９】
切替回路２１０は、ＲＧＢビデオバッファ回路２１２、コンポジットビデオバッファ回路２１４、シリアル信号バッファ回路２１６を備える。ＲＧＢビデオバッファ回路２１２には、ＲＧＢビデオ信号ＲＧＢＳ１、ＲＧＢＳ２が入力され、プロセッサ切替信号ＳＳＷＳに基づいて、いずれか一方のＲＧＢビデオ信号を保持されるとともに出力される。コンポジットビデオバッファ回路２１４には、コンポジットビデオ信号Ｖｉｄｅｏ１、Ｖｉｄｅｏ２が入力され、プロセッサ切替信号ＳＳＷＳに基づいて、いずれか一方のビデオ信号が保持されるとともに出力される。シリアル信号バッファ回路２１８には、シリアルデータＲＳ２３２Ｃ１、ＲＳ２３２Ｃ２が入力され、プロセッサ切替信号ＳＳＷＳに基づいて、いずれか一方のシリアルデータが保持されるとともに出力される。
【００５０】
このように第１の実施形態によれば、電子内視鏡システムに切替装置２００を設けれることにより、第１および第２プロセッサ４０、６０のうち一方のプロセッサがモニタ１５０、コンピュータ１８０が接続される。このような切替装置２００により、モニタ１５０やキーボード１７０などの周辺装置を複数用意する必要がなく、電子内視鏡システムの構築も簡素化されるとともに、検査の作業効率も上がる。
【００５１】
キーボード１７０には、第１および第２プロセッサ４０、６０それぞれの種類に応じた表示が記されたインジケータが設けられており、切替装置２００に接続された第１および第２プロセッサ４０、６０の種類がプロセッサタイプ設定スイッチ２４０によって登録されると、切替装置２００によって選択されるプロセッサに対応したプロセッサの種類の文字がダイオードの発光により照らされる。これにより、オペレータは、今現在使用されているプロセッサの種類を確認することができ、そのプロセッサに対して定められたキーボード１７０の入力操作を行うことができる。すなわち、切替装置２００によって選択されていない他のプロセッサに対する入力操作をキーボード１７０上で誤って行うことがない。
【００５２】
撮像方式の異なる第１プロセッサ４０と第２プロセッサ６０を１つずつ切替装置２００に接続する代わりに、面順次方式あるいは同時単板式の２つのプロセッサを切替装置２００に接続させる構成にしてもよい。また、切替装置２００に接続可能なスコープおよびプロセッサの個数を、３つ以上に設定してもよい。
【００５３】
次に、図８、図９を用いて、第２の実施形態について説明する。
【００５４】
図８は、第２実施形態のインジケータ３００’を示し、図９は第２実施形態のキーボード１７０を示す。第２の実施形態では、第１の実施形態と異なり、キーボード１７０においてダイオードによるインジケータ（発光表示器）の代わりに液晶デバイスを設ける。他の構成に関しては、第１の実施形態と同じである。
【００５５】
インジケータ３００’は、液晶デバイス（液晶パネル）３３０’、ＬＣＤドライバ３４０’、装置名メモリ３５０’を有しており、液晶デバイス３３０’において「装置１」〜「装置８」の文字（プロセッサ情報）が表示される。液晶デバイス３３０’はＬＣＤドライバ３４０’によって駆動され、ＬＣＤドライバ３４０’には装置名メモリ３５０’が接続されている。ＬＣＤドライバ３４０’は、キーボードインジケータ信号ＫＩＳに基づいて、装置名メモリ３５０’にアクセスし、表示すべき装置名を読み出し、液晶デバイス３３０’に表示する。図９では、「装置１」がインジケータ３００’において表示されている。
【００５６】
次に図１０、図１１を用いて、第３の実施形態について説明する。
【００５７】
図１０は、第３実施形態の切替回路２１０を示した図であり、図１１は、第３実施形態におけるモニタ１５０の画面を示した図である。第３の実施形態では、第１、第２の実施形態と異なり、選択されたプロセッサの種類をモニタ１５０に表示する。他の構成に関しては、第１の実施形態と同じである。
【００５８】
切替回路２１０’は、第１の実施形態と同じように、ＲＧＢビデオバッファ回路２１２’、コンポジットビデオバッファ回路２１４’、シリアル信号バッファ回路２１６’を備える。ＲＧＢビデオバッファ回路２１２’には、ＲＧＢビデオ信号ＲＧＢＳ１、ＲＧＢＳ２が入力され、プロセッサ切替信号ＳＳＷＳに基づいて、いずれか一方のＲＧＢビデオ信号が保持されるととも出力される。コンポジットビデオバッファ回路２１４’には、コンポジットビデオ信号Ｖｉｄｅｏ１、Ｖｉｄｅｏ２が入力され、プロセッサ切替信号ＳＳＷＳに基づいて、いずれか一方のコンポジットビデオ信号が保持されるとともに出力される。シリアル信号バッファ回路２１６’には、シリアルデータＲＳ２３２Ｃ１、ＲＳ２３２Ｃ２が入力され、プロセッサ切替信号ＳＳＷＳに基づいて、いずれか一方のシリアルデータが保持されるとともに出力される。
【００５９】
切替回路２１０’から出力されるＲＧＢビデオ信号ＲＧＢＳ１（もしくはＲＧＢＳ２）とコンポジットビデオ信号Ｖｉｄｅｏ１（もしくはＶｉｄｅｏ２）は、スーパーインポーズ回路４００に入力される。スーパーインポーズ回路４００は、ＲＧＢスーパーインポーズ回路４１０、コンポジットスーパーインポーズ回路４２０を備える。スーパーインポーズ回路４００には、キーボードインジケータ信号ＫＩＳが入力されるとともに、モニタ用装置名メモリ４５０が接続されている。スーパーインポーズ回路４００は、キーボードインジケータ信号ＫＩＳに基づいて、モニタ用装置名メモリ４５０にアクセスし、表示すべきプロセッサの種類に応じたキャラクタ信号を読み出す。このとき、所定の位置に文字が表示されるように、タイミングジェネレータ（図示せず）によってキャラクタ信号の出力タイミングが調整される。
【００６０】
図１１に示すように、モニタ１５０には、第１スコープ３０もしくは第２スコープ５０で撮像された画像が静止画ＩＭＧ１、動画ＩＭＧ２として表示される。そして、画像とともに、プロセッサの種類を示す文字（プロセッサ情報）が領域ＡＰＮにおいて表示される。
【００６１】
なお、第１〜第３実施形態では、キーボード１７０のインジケータ３００、３００’を利用しておよびモニタ１５０を使用して選択されたプロセッサの種類をオペレータに知らせているが、それ以外の構成（例えば、切替装置にダイオードのインジケータを設ける）によって、選択されたプロセッサの種類をオペレータに視覚的に知らせてもよい。また、本実施形態ではインジケータ３００として発光ダイオードを適用しているが、ネオン管や白熱ランプなど他の発光表示器を適用してもよい。
【００６２】
【発明の効果】
以上のように本発明によれば、スペースの効率および作業効率が上がるとともに、プロセッサに接続される周辺機器に対して適切な操作を行うことが出きる。
【図面の簡単な説明】
【図１】 本発明に係る電子内視鏡装置の第１実施形態を示すブロック図である。
【図２】 同実施形態のキーボード切替回路を示すブロック図である。
【図３】 同実施形態のプロセッサタイプ設定スイッチを示すブロック図である。
【図４】 同実施形態のキーボードインジケータ切替回路を示す回路図である。
【図５】 同実施形態のインジケータを示すブロック図である。
【図６】 同実施形態のキーボードを示す平面図である。
【図７】 同実施形態の切替回路を示すブロック図である。
【図８】 第２実施形態のインジケータを示すブロック図である。
【図９】 第２実施形態のキーボードを示す平面図である。
【図１０】第３実施形態の切替回路を示すブロック図である。
【図１１】第３実施形態のモニタ画面を示す概念図である。
【符号の説明】
３０ 第１スコープ
４０ 第１プロセッサ
５０ 第２スコープ
６０ 第２プロセッサ
１５０ モニタ（表示装置）
１７０ キーボード（入力装置）
２００ 切替装置
２４０ プロセッサタイプ設定スイッチ（機種登録スイッチ）
３００ インジケータ（選択プロセッサ表示デバイス）
３００’ インジケータ（選択プロセッサ表示デバイス）
ＳＳＷＳ プロセッサ切替信号（選択信号）[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic endoscope apparatus including a scope inserted into a human organ or the like and a processor to which a TV monitor for displaying a captured image is connected, and in particular, includes a plurality of processors. The present invention relates to an electronic endoscope system.
[0002]
[Prior art]
The scope of the electronic endoscope apparatus is provided with an imaging element such as a CCD and a light guide that guides light from the light source to the distal end of the scope, and emits from the distal end of the scope when the scope is inserted into the body cavity. A subject image is formed on the image sensor by reflection of light. On the light receiving surface of the image sensor, an image signal corresponding to the subject image is generated by photoelectric conversion and sent to the processor. The image signal sent to the processor is converted into a video signal (video signal) such as an NTSC signal and output to a display device such as a monitor. Thereby, an operator such as a doctor can observe the captured image on the monitor. In addition to the monitor, there are various processors such as an image recording device for recording the captured image on a film or a magnetic storage medium, a printer for printing the captured image, a keyboard for inputting patient information to the monitor, etc. These devices are connected appropriately.
[0003]
Since the type of the scope (diameter size, etc.) differs depending on the part to be observed, it is necessary to replace the scope each time when observing a plurality of parts such as the bronchi and the large intestine at a time. In addition, when using an electronic endoscope device in a mass examination, the same scope cannot be used for a plurality of people, so it is necessary to change the scope every time one-person diagnosis is completed. Therefore, conventionally, an electronic endoscope system including a plurality of processors is applied, and diagnosis is performed by appropriately connecting a scope to be used to the processor. Thereby, while being able to observe various parts, many patients can be diagnosed.
[0004]
[Problems to be solved by the invention]
However, when a plurality of processors are used, the number of peripheral devices such as monitors, image recording devices, and keyboards connected to the processors increases accordingly. Therefore, a large amount of equipment is required to perform diagnosis and the like, which is costly. In addition, a large space is required to set the system, and the diagnostic efficiency is lowered due to the time and effort required for setting. Furthermore, as the configuration of the electronic endoscope system becomes complicated, operations on peripheral devices connected to a processor such as a keyboard become complicated, and an operator must appropriately operate peripheral devices that are often different for each processor. There is a risk that it will not be possible.
[0005]
SUMMARY OF THE INVENTION An object of the present invention is to provide an electronic endoscope system in which space efficiency and work efficiency can be improved and an appropriate operation can be performed on peripheral devices connected to a processor.
[0006]
[Means for Solving the Problems]
An electronic endoscope system of the present invention includes a plurality of scopes having an image sensor, a plurality of scopes connected to each other, and a plurality of processors that output video signals based on image signals sent from the scopes, A switching device that is connected to a plurality of processors and that selectively outputs a video signal output from any one of the plurality of processors, and a video signal that is connected to the switching device and is output from the switching device. A display device that displays video; an input device that is connected to the switching device and operates a processor selected by the switching device among a plurality of processors; and a selected processor notification unit that notifies the selected processor. Features. By providing such a switching device, it is possible to equip an economically low-cost endoscope system even in an examination using a plurality of scopes and processors, and the diagnostic efficiency is improved. Further, since the processor selected by the selected processor notification means is shown to the operator, the operator can check the currently used processor and perform an input operation according to the currently used processor. Can do.
[0007]
Preferably, the plurality of processors include first and second processors, and the plurality of scopes include a first scope connected to the first processor and a second scope connected to the second processor. Regarding the color imaging method, preferably, one of the first and second processors is a frame sequential method, and the other processor is a simultaneous single-plate method. Usually, the processor system differs depending on the imaging method, and the operation method for the input device also differs depending on the imaging method. The operator can confirm the processor selected when operating the input device, and can perform an input operation corresponding to the selected processor.
[0008]
Also, there are various types of processors among the simultaneous single-plate type and frame sequential type processors, and the operation on the input device is slightly different depending on the type. Therefore, the switching device preferably has a model registration switch for registering the types of the first and second processors connected to the switching device. Thus, the operator is notified of the type of the processor selected from the two processors. Preferably, the selected processor notification means is connected to the switching device based on a switch signal generated in accordance with an operation on the model registration switch and a selection signal representing the processor selected by the switching device among the first and second processors. Lets you know the type of processor you have selected.
[0009]
The input device preferably has a selected processor display device for notifying the selected processor, and in this case, the selected processor notifying means preferably notifies the selected processor on the processor display device. As a result, the operator can check the selected processor while operating the input device. The selected processor display device is, for example, a plurality of light emitting displays corresponding to the number of the plurality of processors, and the selected processor notification means turns on the light emitting display corresponding to the selected processor among the plurality of light emitting displays. To notify the selected processor. Alternatively, the selected processor display device is, for example, a liquid crystal device, and the selected processor notification unit displays processor information representing the selected processor on the liquid crystal device.
[0010]
Alternatively, the selected processor notifying unit may display processor information representing the selected processor on the display device. In this case, the switching device preferably has a superimpose circuit, and the selected processor notification means superimposes a character signal corresponding to the processor information on the video signal. Thereby, the processor information is displayed on the display device.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an electronic endoscope system according to the present invention will be described with reference to the drawings.
[0012]
FIG. 1 is a block diagram showing a first embodiment of an electronic endoscope system.
[0013]
The electronic endoscope system shown in FIG. 1 includes two processors, a first processor 40 and a second processor 60. The first and second processors 40, 60 include a first scope 30 and a second processor 60, respectively. A second scope 50 is connected. Both the first and second processors 40 and 60 are connected to the switching device 200, and the switching device 200 includes a switching circuit 210 and a keyboard switching circuit 220.
[0014]
As an imaging method by the first scope 30 and the first processor 40, a frame sequential method is adopted. More specifically, a white light source 43 such as a xenon lamp is provided in the first processor 40. Between the white light source 43 and the incident end of the light guide 32 in the first scope 30, R (red), G (green) and B (blue) rotating color filters 44 are provided. White light from the white light source 43 is sequentially converted into illumination light of three primary colors by the color filter 44, and illuminates a predetermined part in the body cavity.
[0015]
A first CCD 34, which is an image sensor, is provided at the tip of the first scope 30. The first CCD 34 receives reflected light of each color of R, G, and B of the subject, and corresponds to one frame for each color of R, G, and B. Are sequentially generated. Image signals for one frame generated for each color are sequentially read out from the first CCD 34 and sent to the first processor 40.
[0016]
The first processor 40 is provided with a first video signal processing circuit 41 that processes RGB color image signals sent from the first scope 30. In the first video signal processing circuit 41, gamma correction processing, white balance correction processing, and the like are performed on the image signals for each of the RGB colors. Then, after various processing is performed, a video signal is generated. Specifically, an RGB video signal (RGBS1) in which a synchronization signal is added to an RGB video signal is generated, and a composite video signal (Video1) in which a composite synchronization signal is mixed with a luminance signal and a color difference signal is generated. The The RGB video signal (RGBS1) and the composite video signal (Video1) are output from the first video output terminal IP1 and the first video output terminal VP1 of the first video signal processing circuit 41, respectively.
[0017]
The first processor 40 has a CPU 42, and the operation timing of the white light source 43 and the first video signal processing circuit 41, the readout timing of the RGB video signal in the first CCD 34, the rotational drive of the rotary color filter 44, etc. are controlled by the CPU 42. Be controlled. The first serial port SP1 of the CPU 42 is connected to the switching circuit 210 of the switching device 200. The first keyboard port KP1 of the CPU 42 is connected to the keyboard switching circuit 220 of the switching device 200.
[0018]
The configurations of the second scope 50 and the second processor 60 are the same as those of the first scope 30 and the first processor 40 except that the imaging methods are different, and 20 is added to the reference numerals. In the second scope 50 and the second processor 60, a simultaneous single plate method is applied as an imaging method, and a one-chip color filter (not shown) is provided on the light receiving surface of the CCD 54 at the tip of the scope 50. It has been. The color filter is a complementary color filter, and filter elements of Ye (yellow), Cy (cyan), Mg (magenta), and G (green) are arranged in a mosaic pattern. In the second CCD 54, an image signal for one frame corresponding to the color of the light passing through the complementary color filter is generated.
[0019]
The second video signal processing circuit 61 generates a composite video signal (Video 2) and an RGB video signal (RGBS2) based on the image signal for one frame read from the second CCD 54. The generated RGB video signal (RGBS2) and composite video signal (Video2) are output from the second video output terminal IP2 and the first video output terminal VP2 of the second video signal processing circuit 41, respectively. Further, the second serial port SP2 of the CPU 62 is connected to the switching circuit 210 of the switching device 200, and the second keyboard port KP2 of the CPU 62 is connected to the keyboard switching circuit 220 of the switching device 200.
[0020]
The switching device 200 is connected to one monitor 150, one keyboard 170, an image filing computer 180 having a monitor 185, a keyboard 190, and a printer 160. The switching device 200 selects a processor in which the power is turned on from among the first and second processors 40 and 60. The changeover circuit 200 is provided with a signal changeover switch 230, and each time the signal changeover switch 230 is pressed once, the first processor 40 or the second processor 60 is selected alternatively. Further, the switching circuit 200 is provided with a processor type setting switch 240 connected to the keyboard switching circuit 220, and the first and second connected to the switching device 200 by the operator's operation on the processor type setting switch 240. The type of the two processors 40 and 60 is detected.
[0021]
When the first processor 40 is selected by the switching device 200, the RGB video signal (RGBS 1) output from the first video signal processing circuit 41 is sent to the monitor 150 via the switching circuit 210 of the switching device 200. The monitor 150 displays a color image of the subject imaged by the first scope 30 based on the RGB video signal (RGBS1).
[0022]
The computer 180 is connected to the first serial port SP1 of the CPU 42 in the first processor 40 and the first video output terminal VP2 of the first video signal processing circuit 41 via the switching circuit 210. Thus, serial data (RS232C1) can be transmitted and received, and the composite video signal (Video1) output from the first video signal moat circuit 41 is transmitted to the computer 180. In the computer 180, the composite video signal (Video 1) is subjected to processing such as compression, and thereby an image obtained by a series of inspections is filed on a computer recording medium such as a magneto-optical disk.
[0023]
Further, when the first processor 40 is selected by the switching device 200, the keyboard 170 is connected to the first keyboard port KP1 of the CPU 42 via the keyboard switching circuit 220. On the keyboard 170, an operation instruction to the first processor 40 and an input operation of patient information such as ID, patient name, age, and examination date are performed.
[0024]
On the other hand, when the second processor 60 is selected by the switching device 200, the RGB video signal (RGBS2) is sent to the monitor 150 via the switching circuit 210. As a result, an image captured by the second scope 50 is displayed on the monitor 150. Similarly, the computer 180 is connected to the second serial port SP2 of the CPU 62 and the second video output terminal IP2 of the second video signal processing circuit 61 via the switching circuit 210. As a result, the image obtained by the second scope 50 can be filed on a magneto-optical disk or the like by the computer 180. In addition, the keyboard 170 is connected to the second keyboard port KP2 of the CPU 62 via the keyboard switching circuit 220, thereby enabling the keyboard 170 to input instructions and patient information to the second processor 60. The keyboard 170 is provided with an indicator 300, which notifies the operator of the connection processor selected by the switching circuit 200, as will be described later.
[0025]
As described above, in the electronic endoscope system, the first and second processors 40 and 60 can be selected by the switching device 200, and one monitor 150, keyboard 170, and computer 180 are shared by both processors 40 and 60.
[0026]
FIG. 2 is a block diagram showing the keyboard switching circuit 220 in the switching device 200.
[0027]
The keyboard switching circuit 220 includes a keyboard signal buffer circuit 222, an image switching setting circuit 224, and a keyboard indicator switching circuit 226. The keyboard signal buffer circuit 222 connected to the keyboard 170 once holds the output signal of the keyboard 170 and then outputs it to the first processor 40 or the second processor 60.
[0028]
The image switching setting circuit 224 connected to the keyboard ports KP1 and KP2 detects power line signals output from the keyboard ports KP1 and KP2. That is, the processor in which the power supply is ON is detected from the first and second processors 40 and 60. Then, the image switching setting circuit 224 outputs a processor switching signal SSWS for selecting a processor whose power is on. The output processor switching signal SSWS is sent to the keyboard signal buffer circuit 222, the keyboard indicator switching circuit 226, and the switching circuit 210. The processor switching signal SSWS is also output from the image switching setting circuit 224 by an operation on the signal switching switch 230.
[0029]
The keyboard indicator switching circuit 226 outputs a keyboard indicator signal KIS based on the keyboard setting signal KSS generated by the operation of the processor type setting switch 240 and the processor switching signal SSWS output from the image switching setting circuit 224. When the keyboard indicator signal KIS is sent to the keyboard 170, as will be described later, the processor 300 selected by the switching device 200 in the monitor 180 or the like is indicated by the indicator 300.
[0030]
FIG. 3 is a front view showing the processor type setting switch 240 of the switching device 200.
[0031]
In the present embodiment, four types of processors are prepared for each of the first processor 40 of the frame sequential type and the second processor 60 of the simultaneous single plate type, and each of them can be connected to the switching device 200. In the processor type setting switch 240, four switches SW1, SW2, SW3, and SW4 are provided. The switches SW1 and SW2 are switches that perform processor registration for the first processor 40 and the first scope 30 that are of the field sequential method, and the switches SW3 and SW4 are the second processor 60 and the second scope that are of the simultaneous single plate type. 50 is a switch for performing processor registration for 50. Table 1 shows the correspondence between the open / close states of the switches SW1, SW2, SW3, and SW4 and the types of processors.
[0032]
[Table 1]

[0033]
As shown in Table 1, the four types of frame sequential first processors 40 and the four types of simultaneous single-plate second processors 60 are referred to as “device 1” to “device 8”, respectively. In this embodiment, when setting the electronic endoscope system, the type of the first and second processors 40 and 60 connected to the switching device 200 is set by the processor type setting switch 240. For example, when “device 3” is connected to the switching device 200 as the first processor and “device 7” is connected to the switching device 200 as the second processor, the open / close states of the switches SW1, SW2, SW3, and SW4 are respectively In order, “open”, “closed”, “open”, “closed”. In FIG. 1 described above, the first processor 40 that is “device 1” and the second processor that is “device 5” are connected to the switching device 200, respectively.
[0034]
Usually, the processing system of the processor differs depending on the imaging method, and the keyboard input operation for operating the processor also differs depending on the imaging method. For example, in the first processor 40 of the frame sequential method, the input operation is determined so that the image contour processing is performed when the F1 key of the function key is operated, but in the second processor 60 of the simultaneous single plate type, An image enlargement process is executed by operating the F1 key. Further, even in processors of the same imaging method, keyboard input operations differ when the types are different. However, the type of processor is classified according to the difference in manufacturing. In this embodiment, the types of the first and second processors 60 connected to the switching device 200 are registered in the switching device 200 by operating the processor type setting switch 240.
[0035]
FIG. 4 is a diagram showing the keyboard indicator switching circuit 226.
[0036]
The processor switching signal SSWS sent from the image switching setting circuit 224 (see FIG. 2) and the switch signals output from the switches SW1 to SW4 of the processor type setting switch 240 are input in0, in1, Input to in2, in3, and in4, respectively. Based on these input signals, the keyboard indicator switching circuit 226 outputs a keyboard indicator signal KIS from a built-in keyboard information memory (not shown).
[0037]
The inputs in1 to in4 are connected to the voltage Vcc, and the switches SW1 to SW4 ground the inputs in1 to in4 when closed. That is, the switches SW1 to SW4 send a low level signal “0” to the inputs in1 to in4 when closed and a high level signal “1” when opened. Further, the processor switching signal SSWS sent from the image switching setting circuit 224 to the input in0 becomes a high level signal “1” when the first processor 40 is selected, and when the second processor 60 is selected. It becomes a low level signal “0”.
[0038]
For example, the first processor 40 that is “device 3” and the second processor 60 that is “device 7” are connected to the switching device 200, and the first processor 40 of “device 3” is selected by the switching device 200. In the case (when the video signal output from the first processor is sent to the monitor 150 or the like), the levels of the signals input to the inputs in0 to in4 are “1”, “1”, “0” in order. ”,“ 1 ”,“ 0 ”.
[0039]
The keyboard indicator switching circuit 226 determines the level of the signal input to the inputs in1, in2, or in3, in4 according to the level of the processor switching signal SSWS input to the input in0. Then, the keyboard indicator signal KIS is sent to the keyboard 170 based on the level of the signal input to the inputs in1, in2, or in3, in4. For example, the first processor 40 that is “device 1” and the second processor 60 that is “device 5” are connected to the switching device 200, and the first processor 40 of “device 1” is selected by the switching device 200. In this case, since the level of the processor switching signal SSWS is “1”, the keyboard corresponding to “device 1” based on the level of signals sent from the switches SW1 and SW2 (“1” and “0” respectively). An indicator signal KIS is output. At this time, the level of the signal input to the inputs in3 and in4 is ignored.
[0040]
FIG. 5 is a diagram showing a configuration of the indicator 300 provided on the keyboard 170.
[0041]
The indicator 300 includes a display 310 having eight light emitting diodes LED1 to LED8 to correspond to the first and second processors 40 and 60 prepared in four types, and a keyboard indicator driver for driving each light emitting diode. 320. A keyboard indicator signal KIS output from the keyboard indicator switching circuit 226 is input to the keyboard indicator driver 320. Then, as shown in Table 2, the keyboard indicator driver 320 causes any one light emitting diode to emit light based on the keyboard indicator signal KIS. In Table 2, the keyboard indicator signal KIS is expressed as E1 to E8 in order to correspond to eight light emitting diodes.
[0042]
[Table 2]

[0043]
For example, when the first processor 40 of “device 1” and the second processor 60 of “device 5” are connected to the switching device 200 and the first processor 40 of “device 1” is selected by the switching device 200, “ The signal “E1” is sent to the keyboard indicator driver 320.
[0044]
FIG. 6 is a plan view showing the external appearance of the keyboard 170.
[0045]
A signal cable 172 for inputting / outputting keyboard signals and a signal cable 174 for inputting keyboard indicator signals KIS are connected to the keyboard 170, and transmission / reception of signals is executed.
[0046]
In the indicator 300, “device 1”, “device 2”, “device 3”, “device 4” corresponding to the display of the types of the first and second processors 40 and 60 shown in Tables 1 and 2. , “Device 5”, “device 6”, “device 7”, “device 8” are indicated, and the arrangement of the light-emitting diodes LED1 to LED8 is the character display of these “device 1” to “device 8”. It corresponds to. The type of character display on the processor selected by the switching device 200 is illuminated when the corresponding light emitting diode is lit.
[0047]
For example, if the first processor 40 of “device 1” and the second processor 60 of “device 5” are connected to the switching device, the first processor 40 of “device 1” is selected by the switching device 200. The character “device 1” is illuminated by the lighting of the diode LE1, while the character “device 5” is illuminated by the lighting of the diode LE5 if the second processor 40 of “device 5” is selected by the switching device 200. .
[0048]
FIG. 7 is a diagram showing details of the switching circuit 210.
[0049]
The switching circuit 210 includes an RGB video buffer circuit 212, a composite video buffer circuit 214, and a serial signal buffer circuit 216. The RGB video buffer circuit 212 receives RGB video signals RGBS1 and RGBS2, and holds and outputs one of the RGB video signals based on the processor switching signal SSWS. The composite video buffer circuit 214 receives composite video signals Video1 and Video2, and holds and outputs one of the video signals based on the processor switching signal SSWS. Serial data RS232C1 and RS232C2 are input to the serial signal buffer circuit 218, and either serial data is held and output based on the processor switching signal SSWS.
[0050]
Thus, according to the first embodiment, by providing the switching device 200 in the electronic endoscope system, one of the first and second processors 40, 60 is connected to the monitor 150 and the computer 180. The With such a switching device 200, it is not necessary to prepare a plurality of peripheral devices such as the monitor 150 and the keyboard 170, the construction of the electronic endoscope system is simplified, and the inspection work efficiency is increased.
[0051]
The keyboard 170 is provided with an indicator having a display according to the type of each of the first and second processors 40 and 60, and the type of the first and second processors 40 and 60 connected to the switching device 200. Is registered by the processor type setting switch 240, the character of the processor type corresponding to the processor selected by the switching device 200 is illuminated by the light emission of the diode. As a result, the operator can confirm the type of the processor currently used, and can perform an input operation of the keyboard 170 determined for the processor. That is, an input operation for another processor not selected by the switching device 200 is not erroneously performed on the keyboard 170.
[0052]
Instead of connecting the first processor 40 and the second processor 60 having different imaging methods one by one to the switching device 200, two frame sequential or simultaneous single-plate processors may be connected to the switching device 200. Further, the number of scopes and processors connectable to the switching device 200 may be set to three or more.
[0053]
Next, a second embodiment will be described with reference to FIGS.
[0054]
FIG. 8 shows an indicator 300 ′ of the second embodiment, and FIG. 9 shows a keyboard 170 of the second embodiment. In the second embodiment, unlike the first embodiment, a liquid crystal device is provided in the keyboard 170 instead of an indicator (light emitting display) using a diode. Other configurations are the same as those in the first embodiment.
[0055]
The indicator 300 ′ includes a liquid crystal device (liquid crystal panel) 330 ′, an LCD driver 340 ′, and a device name memory 350 ′. In the liquid crystal device 330 ′, characters “device 1” to “device 8” (processor information) Is displayed. The liquid crystal device 330 ′ is driven by an LCD driver 340 ′, and a device name memory 350 ′ is connected to the LCD driver 340 ′. The LCD driver 340 ′ accesses the device name memory 350 ′ based on the keyboard indicator signal KIS, reads the device name to be displayed, and displays it on the liquid crystal device 330 ′. In FIG. 9, “device 1” is displayed on the indicator 300 ′.
[0056]
Next, a third embodiment will be described with reference to FIGS. 10 and 11.
[0057]
FIG. 10 is a diagram illustrating the switching circuit 210 according to the third embodiment, and FIG. 11 is a diagram illustrating a screen of the monitor 150 according to the third embodiment. In the third embodiment, unlike the first and second embodiments, the type of the selected processor is displayed on the monitor 150. Other configurations are the same as those in the first embodiment.
[0058]
As in the first embodiment, the switching circuit 210 ′ includes an RGB video buffer circuit 212 ′, a composite video buffer circuit 214 ′, and a serial signal buffer circuit 216 ′. The RGB video buffer circuit 212 ′ receives RGB video signals RGBS 1 and RGBS 2 and holds and outputs one of the RGB video signals based on the processor switching signal SSWS. The composite video buffer circuit 214 ′ receives composite video signals Video1 and Video2, and holds and outputs either composite video signal based on the processor switching signal SSWS. Serial data RS232C1 and RS232C2 are input to the serial signal buffer circuit 216 ′, and one of the serial data is held and output based on the processor switching signal SSWS.
[0059]
The RGB video signal RGBS1 (or RGBS2) and the composite video signal Video1 (or Video2) output from the switching circuit 210 ′ are input to the superimpose circuit 400. The superimpose circuit 400 includes an RGB superimpose circuit 410 and a composite superimpose circuit 420. A keyboard indicator signal KIS is input to the superimpose circuit 400, and a monitor device name memory 450 is connected thereto. The superimpose circuit 400 accesses the monitor device name memory 450 based on the keyboard indicator signal KIS, and reads a character signal corresponding to the type of processor to be displayed. At this time, the output timing of the character signal is adjusted by a timing generator (not shown) so that the character is displayed at a predetermined position.
[0060]
As shown in FIG. 11, images captured by the first scope 30 or the second scope 50 are displayed on the monitor 150 as a still image IMG1 and a moving image IMG2. Along with the image, characters (processor information) indicating the type of processor are displayed in the area APN.
[0061]
In the first to third embodiments, the operator is notified of the type of processor selected using the indicators 300 and 300 ′ of the keyboard 170 and the monitor 150, but other configurations (for example, The switching device may be provided with a diode indicator) to visually inform the operator of the selected processor type. In this embodiment, a light emitting diode is applied as the indicator 300, but other light emitting displays such as a neon tube or an incandescent lamp may be applied.
[0062]
【The invention's effect】
As described above, according to the present invention, space efficiency and work efficiency can be improved, and appropriate operations can be performed on peripheral devices connected to the processor.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a first embodiment of an electronic endoscope apparatus according to the present invention.
FIG. 2 is a block diagram showing a keyboard switching circuit according to the embodiment.
FIG. 3 is a block diagram showing a processor type setting switch of the embodiment.
FIG. 4 is a circuit diagram showing a keyboard indicator switching circuit according to the embodiment;
FIG. 5 is a block diagram showing an indicator of the same embodiment.
FIG. 6 is a plan view showing the keyboard of the embodiment.
FIG. 7 is a block diagram showing a switching circuit of the same embodiment;
FIG. 8 is a block diagram showing an indicator of the second embodiment.
FIG. 9 is a plan view showing a keyboard according to a second embodiment.
FIG. 10 is a block diagram illustrating a switching circuit according to a third embodiment.
FIG. 11 is a conceptual diagram showing a monitor screen according to a third embodiment.
[Explanation of symbols]
30 First scope
40 First processor
50 Second scope
60 Second processor
150 Monitor (display device)
170 Keyboard (input device)
200 switching device
240 Processor type setting switch (model registration switch)
300 indicator (selected processor display device)
300 'indicator (selected processor display device)
SSWS Processor switching signal (selection signal)

Claims (12)

A plurality of scopes having an image sensor;
A plurality of processors connected to each of the plurality of scopes and outputting a video signal based on an image signal sent from the scope;
A switching device that is connected to the plurality of processors and selectively outputs the video signal output from any one of the plurality of processors;
A display device connected to the switching device and displaying an image of the video signal output from the switching device;
An input device connected to the switching device and operating a processor selected by the switching device among the plurality of processors;
Selection processor notification means for visually informing the selected processor ;
The switching device has a model registration switch for registering the type of each of the plurality of processors connected to the switching device;
The selected processor notifying means notifies the type of the selected processor based on a switch signal generated in accordance with an operation on the model registration switch and a selection signal representing a processor selected by the switching device among the plurality of processors. An electronic endoscope system characterized by The input device has a selected processor display device for indicating the selected processor;
The electronic endoscope system according to claim 1, wherein the selected processor notifying unit notifies the selected processor on the processor display device.   The electronic endoscope system according to claim 1, wherein the selected processor notification unit displays processor information representing the selected processor on the display device. The selected processor display device comprises a plurality of light emitting indicators, the number of which is the number of the processors;
The selected processor notifying means notifies the selected processor by turning on a light emitting display corresponding to the selected processor among the plurality of light emitting displays. Electronic endoscope system. The selected processor display device is a liquid crystal device,
The electronic endoscope system according to claim 2, wherein the selected processor notification unit displays processor information representing the selected processor on the liquid crystal device. The switching device has a superimpose circuit;
4. The electronic endoscope system according to claim 3, wherein the selection processor notifying unit superimposes a character signal corresponding to the processor information on the video signal. The plurality of processors include first and second processors, and the plurality of scopes include a first scope connected to the first processor and a second scope connected to the second processor. ,
2. The electronic endoscope according to claim 1, wherein one of the first and second processors is a frame sequential method and the other processor is a simultaneous single plate type. system. A plurality of scopes having an image sensor;
A plurality of processors connected to each of the plurality of scopes and outputting a video signal based on an image signal sent from the scope;
A switching device that is connected to the plurality of processors and selectively outputs the video signal output from any one of the plurality of processors;
A display device connected to the switching device and displaying an image of the video signal output from the switching device;
An input device that is connected to the switching device and operates a processor selected by the switching device among the plurality of processors; and a selected processor notification unit that visually notifies the selected processor;
The plurality of processors include first and second processors, and the plurality of scopes include a first scope connected to the first processor and a second scope connected to the second processor. As for the imaging method, one of the first and second processors is a frame sequential method, and the other processor is a simultaneous single plate type,
The switching device has a model registration switch for registering the types of the first and second processors connected to the switching device, and the selected processor notification means follows an operation on the model registration switch. An electronic endoscope system that notifies a type of the selected processor based on a switch signal that is generated and a selection signal that represents a processor selected by the switching device among the first and second processors. A plurality of processors each having a plurality of scopes each having an image pickup device are connected, and a plurality of processors that output video signals based on image signals sent from the scopes are connected,
A display device that displays video according to the video signal and an input device that operates the plurality of processors are connected,
Switching means for selectively outputting the video signal output from any one of the plurality of processors to the display device;
Input processor selection means for sending an input signal generated in the input device to a processor selected by the switching means among the plurality of processors;
Selected processor notification means for displaying processor information representing the type of the selected processor on the display device ;
A model registration switch for registering the type of each of the plurality of connected processors,
The selected processor notification means uses the selected processor type as processor information based on a switch signal generated in accordance with an operation on the model registration switch and a selection signal representing the processor selected by the switching device among the plurality of processors. A switching device for an electronic endoscope system, characterized in that the display is displayed on the display device. A plurality of processors each having a plurality of scopes each having an image pickup device are connected, and a plurality of processors that output video signals based on image signals sent from the scopes are connected,
A display device that displays video according to the video signal and an input device that operates the plurality of processors are connected,
Switching means for selectively outputting the video signal output from any one of the plurality of processors to the display device;
Input processor selection means for sending an input signal generated in the input device to a processor selected by the switching means among the plurality of processors;
Selection processor notification means for notifying the selected processor ;
A model registration switch for registering the type of each of the plurality of connected processors ,
The input device has a selected processor display device capable of informing the type of the selected processor;
The selected processor notification means is based on a switch signal generated in accordance with an operation on the model registration switch and a selection signal representing the processor selected by the switching device among the plurality of processors, and the processor display device selects the selected processor. A switching device for an electronic endoscope system, characterized in that the type is notified . A plurality of processors each having a plurality of scopes each having an image pickup device are connected, and a plurality of processors that output video signals based on image signals sent from the scopes are connected,
A display device that displays video according to the video signal and an input device that operates the plurality of processors are connected,
Switching means for selectively outputting the video signal output from any one of the plurality of processors to the display device;
Input processor selection means for sending an input signal generated in the input device to a processor selected by the switching means among the plurality of processors;
Selection processor notification means for displaying processor information representing the selected processor on the display device;
The plurality of processors include first and second processors, and the plurality of scopes include a first scope connected to the first processor and a second scope connected to the second processor. As for the imaging method, one of the first and second processors is a frame sequential method, and the other processor is a simultaneous single plate type,
A model registration switch for registering the type of each of the connected first and second processors;
The selected processor notification means is based on a switch signal generated in accordance with an operation on the model registration switch and a selection signal representing a processor selected by the switching device among the first and second processors. Is displayed on a display device as processor information. A switching device for an electronic endoscope system, wherein A plurality of processors each having a plurality of scopes each having an image pickup device are connected, and a plurality of processors that output video signals based on image signals sent from the scopes are connected,
A display device that displays video according to the video signal and an input device that operates the plurality of processors are connected,
Switching means for selectively outputting the video signal output from any one of the plurality of processors to the display device;
Input processor selection means for sending an input signal generated in the input device to a processor selected by the switching means among the plurality of processors;
Selection processor notification means for notifying the selected processor;
The input device has a selected processor display device capable of informing the type of the selected processor;
The plurality of processors include first and second processors, and the plurality of scopes include a first scope connected to the first processor and a second scope connected to the second processor. As for the imaging method, one of the first and second processors is a frame sequential method, and the other processor is a simultaneous single plate type,
A model registration switch for registering the type of each of the connected first and second processors;
The selected processor notification means is configured to select the display signal in the selected processor display device based on a switch signal generated in accordance with an operation on the model registration switch and a selection signal representing a processor selected by the switching device among the first and second processors. A switching device for an electronic endoscope system, characterized by notifying a type of a selected processor.

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