WO1995017845A1

WO1995017845A1 - Endoscopic video system

Info

Publication number: WO1995017845A1
Application number: PCT/DE1995/000001
Authority: WO
Inventors: Klaus-Martin Irion
Original assignee: Karl Storz Gmbh & Co.
Priority date: 1993-12-31
Filing date: 1995-01-02
Publication date: 1995-07-06
Also published as: DE19580002D2

Abstract

Described is an endoscopic video system with an illuminating light source, a fibre-optic waveguide (5, 5') which transmits the light to at least one distal light exit and, at least one colour-image video recorder (4) with its associated optical system (7). The invention is characterized in that at least one spectral filter (8) is located in the illuminating light source or in the fibre-optic waveguide, the filter being designed in such a way that it adapts the spectral distribution of the visible light from the light source to the spectral sensitivity of the colour-image recorder (4).

Description

Endoscopic video system

Description

Technical field

The invention relates to an endoscopic video system.

In endoscopy and especially in minimally invasive therapy, video systems have been used increasingly for some time in order to display the recorded image on a TV monitor and / or to record it by means of a video recorder and, if necessary, to further process it with an image processing system.

State of the art

The known endoscopic video systems have an illuminating light source, a light guide system that guides the light to at least one distal light outlet, and at least one video color image sensor with an associated optical system and a downstream electronic processing system.

Whereas in the past video systems were generally only used for co-observation, direct visual observation is currently being dispensed with more and more and the object to be observed is only recorded and displayed with the video system. However, illuminating light sources are still used as illuminating light sources, which have the same spectral course as the illuminating light sources. have light sources that are used to illuminate a visually observed object. The spectral profile of these conventional illuminating light sources is chosen so that a "natural" color impression is produced when viewed visually.

Since the known image recorders and, in particular, color CCD image recorders have a spectral sensitivity that differs from that of the human eye, it is necessary and generally state of the art to correct daylight in the observation beam path of the video system in front of the image pickup. Attach conversion filters. Such a conversion filter reduces the light output striking the image sensor in the visible range by at least 30%.

Because of the very high red sensitivity of the image sensor, the conversion filter has a very high attenuation, especially in this area.

Description of the invention

According to the invention, it has now been recognized that the arrangement of the conversion filter directly in front of the image sensor has a number of disadvantages in endoscopic video systems:

The main disadvantage is that at least 30% of the light output falling on the color image sensor is not used because of the conversion filter in front of the image sensor and is not required because of the spectral characteristics of the image sensor, but is nevertheless coupled into the body and converted into heat. Since the light output falling from the object (tissue) onto the color image sensor is at least one order of magnitude lower than the light output coupled into the body, it is advisable to avoid unnecessary heat by inserting the conversion filter into the light guide system or to integrate the illuminating light source, ie to place it outside the body.

For this reason, according to the invention, at least one spectral filter is arranged in the illuminating light source or in the light guide system, which is designed in such a way that it adjusts the spectral distribution of the visible light from the light source to the spectral sensitivity of the color image sensor. The arrangement of the conversion or. Spectral filters in the illumination beam path have the advantage over the arrangement of the filter in the observation beam path that the light output required to illuminate the object to be observed is at least 30% less than when the filter is arranged in the observation beam path.

The possibly still necessary infrared cut filter (claim 12) for suppressing the quality-impairing infrared radiation can simply be applied to the cover glass of the CCD sensor if the conversion filter is omitted.

The invention can be used both with color image recorders arranged distally, ie in the endoscope or instrument without an image relay, and with video cameras arranged proximally, which are flanged onto the eyepiece of the endoscope, for example, or in front of the eyepiece or without the eyepiece directly capture the image of the image relay, such as a rod lens system. According to the development specified in claim 2, the filter can be assembled in such a way that at least 25% of the light output in this range is blocked in the wave range from 400 to 700 nm.

For this purpose, the filter can have the following transmission values:

T (= 600 nm) <80%

T (% = 650 nm) <40%

T (% = 675 nm) <30%

T ( _/ l = 700 nm) <10%.

In principle, any filter, but preferably dichroic filter, can be used as the filter.

Claims 5 to 7 specify various options for the arrangement of the filter:

The arrangement of the filter on the proximal entry surface of the light guide system has the advantage that the light guide system is acted upon with the lowest possible light output without any intervention in the illuminating light source.

Thus, in this arrangement, as in the arrangement specified in claim 6, existing illumination light sources that are matched to the visual observation can continue to be used without modification or intervention in the light source.

Endoscopic video systems generally have an instrument and in particular an endoscope that is inserted into a hollow rough, for example, can be used in a human body, and in which a light guide for the illuminating light is integrated. On the proximal side of the instrument, a coupling element - for example a light standard plug - is provided, by means of which the light guide of the instrument can be connected to a light guide cable, which in turn is connected to the illuminating light source.

This embodiment is i.a. preferred if a video camera is used which is coupled proximally to an endoscope, since then both commercially available endoscopes and illuminating light sources can be used.

In order to be able to continue to use commercially available light guide cables for connecting the instrument or endoscope to the illuminating light source, the filter can be placed on the light entry surface of the coupling element on the instrument or endoscope or, according to claim 6, on the distal exit surface of the instrument and thus of the light guide system are applied. This possibility has the advantage that it is structurally particularly easy to implement. In addition, it allows the separation of light guide cable and endoscope.

Of course, the filter can also be arranged in the illuminating light source (claim 7). If the illuminating light source is designed in such a way that the filter can be removed from the illuminating beam path, the illuminating light source can be used both for visual observation and for pure video detection. A simple technical configuration for the arrangement of the filter in the illuminating light source is characterized in claim 9, according to which the filter can be automatically or manually pivoted in or out of the illuminating beam path. For the automatic swiveling in and out, the plug of the light guide cable can, for example, be provided with a code which indicates whether visual observation or image acquisition is carried out with a color image sensor.

The filter can in particular in front of the light guide entry surface in the illuminating light source, i.e. be arranged the surface by means of which the light is coupled into the light guide cable (claim 10).

In claim 11 - not conclusively - various light sources that can be used in a video system according to the invention are specified.

Brief description of the drawings

The invention is described below by way of example without limitation of the general inventive concept on the basis of an exemplary embodiment with reference to the drawing, to which reference is expressly made with regard to the disclosure of all details according to the invention not explained in detail in the text. Show it:

1 shows an embodiment for an endoscopic video system according to the invention,

2 shows a transmission curve of a conversion filter used according to the invention. Description of an embodiment

1 shows a partially sectioned side view and a front view of an embodiment for an endoscopic video system. Without restricting the general applicability of the invention, the video system has an endoscope 1, in which a color image pickup 4 is arranged distally. Of course, the invention can also be used for proximally arranged color image recorders.

The color image pickup 4 is, for example, a charged coupled device (CCD). The image of an endoscopic scene recorded by the CCD 4 by means of a lens 7 is further processed by a downstream processing circuit 3, which can be a hybrid circuit, for example. With 6 a low-pass filter or an infrared cut filter is designated.

The circuit 3 is connected via electrical lines 2 in the endoscope 1 and a cable 10 removably connected to the endoscope 1 with a plug 11 to a conventional video unit (not shown) so that the object, i.e. the endoscopic scene can be viewed on a monitor, for example.

To illuminate the endoscopic scene, the endoscope 1 has a light guide 5, which can be arranged in the shape of a hollow cylinder, in particular, on the outer region of the interior of the endoscope shaft.

To couple the light from an illuminating light source, not shown, into the light guide 5, a light guide cable 9 is provided, which is provided with known and not further designated plugs and which has a light guide 5 ¹ contains, which is connected on the light entry side with the illuminating light source and on the light exit side with the light guide 5.

In the exemplary embodiment shown, the cables 9 and 10 are partially combined to form a cable 12.

According to the invention the light of the illumination light source 9 is coupled via a conversion filter 8 in the light guide 5 of the cable ¹ at the source for connection to the Beleuchtungslicht¬ provided Lichteinkoppelstutzen.

2 shows an example of the transmission of this conversion filter 8 for different wavelengths X. The transmission curve can vary depending on the image pickup unit 4 used, to which the filter 8 is to be adapted.

The invention has been described above on the basis of an exemplary embodiment without restricting the general applicability. In particular, the invention can be used both with rigid and with flexible endoscopes with proximally or distally arranged image recorders.

Claims

Patent claims

1. Endoscopic video system with an illuminating light source, a light guide system (5, 5 ') which guides the light to at least one distal light exit, and at least one video color image sensor (4) with an associated optical system (7), characterized in that at least one spectral filter (8) is arranged in the illuminating light source or in the light guide system and is designed in such a way that it adjusts the spectral distribution of the visible light from the light source to the spectral sensitivity of the color image sensor.

2. System according to claim 1, characterized in that the filter (8) is so confectioned that in the wave range of 400 to 700nm at least 20% of the light output in this range are blocked.

3. System according to claim 1 or 2, characterized in that the filter (8) has the following transmission values:

T (= 600 nm) <80

T (^ = 650 nm) <40

T (. = 675 nm) <30

T (^ = 700 nm) <10

4. System according to one of claims 1 to 3, characterized in that the filter (8) is a dichroic filter.

5. System according to one of claims 1 to, characterized in that the filter (8) is applied to the proximal entry surface of the light guide system (5 ').

6. System according to one of claims 1 to 4, characterized in that the filter is applied to the distal exit surface of the endoscope.

7. System according to any one of claims 1 to 4, characterized in that the filter is arranged in the lighting light source.

8. System according to claim 7, characterized in that the filter can be removed from the lighting beam path.

9. System according to claim 8, characterized in that the filter in or out of the illuminating beam path automatically or manually on or. can be swung out.

10. System according to any one of claims 7 to 9, characterized in that the filter is arranged in front of the Lichtlei¬ ter entry surface in the illuminating light source.

11. System according to any one of claims 1 to 10, characterized in that the illuminating light source has at least one halogen, xenon, halide or other metal vapor lamp.

12. System according to one of claims 1 to 11, characterized in that an infrared cut filter (6) is applied to the image sensor (5).