DE4439508A1 - Increasing focal depth for optical observation or imaging system esp. optical microscopy - Google Patents

Abstract

The increasing focal depth method involves an object (7) to be investigated, pref. of small dimensions, which is top and/or through illuminated. An image, esp. a magnified image, of it is formed using a microscope lens (1), and direct observation, with measurement value acquisition, imaging (3), processing (4) and/or storage processes conducted by a central processor (6). To achieve sharp images of at least two surfaces at different depths without subsequent adjustment, the surfaces are pref. simultaneously illuminated (2) with light from at least two different directions and two narrow separate monochromic wavelength regions, esp. bands, and images formed of the surfaces simultaneously on an imaging surface using a basic focus adjustment.

Description

The invention relates to methods for increasing the Depth of field for optical, in particular microscope-optical measurement acquisitions Illustrations and the like. As well as on a device for carrying out the Ver driving.

There is a greater number of suggestions for improving Depth of field of optical systems, especially microscopes the, and it is only an example to DE-OS 21 11 648, according to which a scan of an image plane from a plurality of such planes follows and after saving a two-dimensional image reproduction takes place DE-PS 27 12 837, which the use of a close to the axis a high Proposing transmission coefficients suggests on the WO 90/07723 using a transmission grating in the beam path or on the WO 92/18894 with a novel lighting system for a highly sensitive Microscope pointed out. EP-A2 468 817 and CH-PS are also cited 600 359.

The specimens to be viewed through a microscope always have a certain finite thickness. However, conventional microscopes have increased with increasing Magnification sinking, shallow depth of field. With a usual light micros It is only possible to use one specific cut surface at a time to consider each point in time with sufficient sharpness. However, it is him required to consider the setting of the other cut surface Microscope, which makes it very difficult to change an entire area to consider a plurality of depths of the specimen at once. Furthermore, the contrast in images outside the focal length can be reversed become, which leads to a faulty observation level.

The optical enlargement of the visual image of an object in the Microscope results on the one hand from the reproductive speed difference reference of light in a suitable light guiding body / body system and in its environment, on the other hand from the geometry of the overall arrangement (Object-optical arrangement-imaging plane).

The geometric shape of an optical lens (lens system) determines the wavelength-specific optical magnification values that can be achieved at a constant object / imaging plane distance. The shorter wavelengths you choose, the higher magnifications can be achieved and vice versa.

• 1. In the case of conventional broadband lighting, a certain te level of the object with the help of the lens system on an observation level pictured. A geometry-related enlargement is part of the plane spacing. The Object planes deviating from this distance have different ver larger values and reduced by interference effects on the intensity  Mapping level mapped. The result is a superposed picture, which contains several object plane images enlarged depending on the distance. The Ab The sharpness of formation takes on maximum values at a certain level, below and it quickly decreases above this distance value. There is a minor one Object image plane distance area where the image did focus remains practically usable. However, this area decreases with the Ver magnification rapidly, and if the magnification of the arrangement turns to the top Approaches the wavelength range of the lighting spectrum, the Depth of field to a wavelength size.
• 2. In the case of monochrome (one wavelength) lighting becomes one certain level of the object with the help of a lens system on a Observation level mapped. Belongs to an object imaging plane distance always a certain magnification value.

The object planes deviating from this distance are also ab soft magnification and intensity mapped on the image level.

The result is a superposed image in which one level of the Object is mapped with an arrangement-specific magnification. All other Object planes are distorted due to distance deviation, due to interference effects reduced in intensity.

The invention has set itself the task that o.a. disadvantage and the disadvantages known and for the most part also technically complex Avoid attempting solutions and suggestions and make use of them available standing, modern narrow band lighting technology a technically uncomplicated to create a highly informative lighting system that robust light microscopy able to give new and unexpected impulses is.

The phenomenon that can be observed when a Object to be examined with several monochrome or narrow-band light sources is illuminated and that leads to a common, simultaneous Sharp, originating from several levels of different depths in the object two-dimensional image of the deeply captured space is achieved.

Accordingly, the subject of the present invention is a method to increase the depth of field in the context of optical, especially microscope optical, acquisition, measurement, observation and / or imaging systems or -techniques, with an object to be examined and / or imaged before tends to be of small dimension, incident light and / or transmitted light is applied, and by means of optics, in particular microscope optics, an image, in particular a  enlarged image of the same formed and a direct observation and / or Observation, measurement acquisition, recording, processing or processing and / or memory device is supplied, which method thereby ge is characterized in that to achieve sharp images from at least two areas or levels of different depths of the object are the same avoiding an initial setting of subordinate, further ons position (s) or adjustment (s) with light from at least two of them different and isolated from each other - at least essentially Wavelength ranges, in particular wavelength bands, is applied and that of the optical system - preferably according to the corresponding basic focus lung - formed images from the at least two depths of the object - at least essentially - simultaneously in an imaging area, in particular -level, mapped and a direct observation and / or one Observation, measurement acquisition, recording, processing, processing and / or Storage device is supplied.

The object imaging planes arise according to the waves differences in length. Shorter wavelengths form the closer ones Object levels, longer waves the more distant levels on the one image level. The superposed image contains the information from the Wavelength number of corresponding object planes, this creates one correct "sharp" image of the object on several levels.

The individual lighting wavelengths or narrowband spectral areas must have at least spectral distances corresponding to the bandwidth have from each other to the image sharpness in different depth planes to be able to secure. The spectral range that can be used and the range that can be achieved thereby Depth of image is in itself limited only by the implementation technology and is constantly changing due to ongoing developments.

According to the current state of development it is preferred, monochromatic or narrow-band light in the claim To use 2 spectral ranges mentioned according to the invention, z. B. UV through common CaF₂ optics or other customized optical materials for Get involved.

As for the above-mentioned distance of the monochrome spectral bands of the light to be used affects each other, has proven to be quite acceptable procedure leading to high quality results those proven according to claim 3. As a rule of thumb, for example, that the smallest distance from the light source to the emission  Spectral bands of one another should be at least as large as the width of one Band.

In this context, it is regarding sharp band separation favorable to assume a band gap, which the conditions regarding still "allowed" spectral band overlaps according to claim 4 fulfilled.

As for the range of the individual for the multi-monochrome Objective provided discrete spectral bands, so are this Information about preferred values included in claim 5.

It has been observed that too narrow spectral bandwidths, e.g. B. in Range of 1 nm or below for interfering interference and "speeckles" being able to lead.

At this point, let's be clear about two with light Wavelength bands achievable, maximum distance of two sharp images the depths of the object refer to a rule of thumb that states that the achievable depth of field is the product of system magnification and spectral bandgap is directly proportional, e.g. B. at 100 times Magnification and 20 nm distance between the spectral bands of the object Light provided the distance between the two in a single light emitter Imaging plane at the same time sharply imaged planes from each other about 2 µm is.

To ensure optimal, free of shadows and optical illusions Achieving imaging quality has become an approach according to the claim 6 proved to be cheap in any case.

For high image quality because of its special narrow-band character ter based, the use of is provided according to claim 7 Light emitters cheap.

Claim 8 is particularly within the scope of the invention Arrangements and training forms of the Narrowband light emitter information.

To increase what can be achieved with the technology according to the invention Information content are different advantageous in claim 9 Suggestions for optimal system-internal coordination and optimization of the Single component characteristics of the available infra structure on top of each other.

The same applies to the strategy and characteristics of the claim 10th

System-integral corrections and compensations enable one Procedure encompassed by claim 11, with particular reference to this  reference is that computer support and use of flexible image processing systems are of particular advantage.

A large number of ways of displaying objects, possibly Equal to "life" and in motion, a process finishing variant opens which is outlined by claim 12. Such a method enables z. B. a sharp, highly informative reproduction of what is currently taking place, biological processes in cells, such as B. metabolic processes, Cell organ (vacuole) movements, membrane deformations and. the like

Another essential object of the invention is a device in particular microscope or the like, for acquisition, measurement, observation and / or Illustration of objects, especially small dimensions, with increased Depth of field, especially to perform a procedure like the one above is described, and the essential features thereof are that essentially around the object section and / or below the object table of a preferably optically corrected microscope, at least one, preferably ring-like, light emitter carrier body with at least two groups of for Object table or towards the object to be examined and / or depicted directed light from at least two different and emitting at least substantially isolated wavelength bands or producing narrow spectral band light emitters, in particular LED, Laser diodes and / or gas discharge lamps, which are preferred are adjustable in intensity, is arranged.

With an approximately annular lighting bracket is such. B. the special advantage of a completely problem-free retrofitting of a depth of field optimized microscope in an ordinary light microscope and vice versa.

A particularly simple solution for the lighting device for a device according to the invention claims 15.

Claim 16 deals with a cost-effective Minimization of the necessary number of active light sources by using the Optical fiber technology and gives corresponding technical and information-promoting solutions, although of course the demand for increased Luminous intensity of the light emitter exists.

One particularly preferred because it is highly flexible is the modern one Optoelectronics and video technology enable image evaluation, in particular in 3D form, as is the subject of claim 17.

The invention is explained in more detail with reference to the drawing.

Show it

Fig. 1 is a basic scheme of the invention and Figs. 2 and 3 a preferred embodiment of the device according to the invention a detail of its lighting system.

The arrangement shown in Fig. 1 consists of a conventional light microscope 1 , coupled with multi-band light emitters 2 for object lighting and coupled to the optical output with optoelectronic image converter / image reproduction / image processing system. The multi-spectral band light emitter system 2 ensures homogeneous illumination of the object 7 with either individual wavelengths or with narrow spectral band light.

The enlarged visual image of the microscope is imaged on the optical surface of the image converter 3 . The image converted into electrical information can be displayed by means of an image display system 4, that is to say an image monitor or an image processing system with an image display system 4 . The power supply is designated 5 . A central control unit 6 monitors, controls and regulates the individual functions and components of the system.

The side view of Fig. 2 shows schematically a microscope 1 , the lens side of a toroidal support body 20 with an object to be examined 7 on the microscope stage 10 light of two different spectral bands emitting light emitters, for. B. LED or LD spotlights 2 , 2 ', is surrounded. It can be seen there how, when the object 7 is simultaneously illuminated with monochrome light from two different spectral positions, two levels 70, 71 of different depth positions are "addressed" in the object 7 and at the same time both with full sharpness on a sensor level 30 of the optoelectronic transducer 3 which is set in a fixed manner be mapped.

Finally, FIG. 3 shows an annular lighting support body 20 from its light emitter side and in a side view. It is easy to see how - here on a single circle - three groups of light emitters S1, S2, S3, z. B. LED or laser diode emitter, with three under different spectral band emission characteristics are each arranged evenly distributed over the circumference of the circle, so that advantageous homogeneous illumination of an object to be examined can be ensured for all spectral bands provided.

Claims (17)

1. A method for increasing the depth of focus in the context of optical, in particular microscope-optical, detection, measurement, observation and / or imaging systems or techniques, whereby an object to be examined and / or to be imaged, preferably of small dimensions, illuminates - And / or is acted upon by light, and by means of optics, in particular microscope optics, an image, in particular an enlarged image thereof, is formed and direct observation and / or observation, measurement value acquisition, recording, processing or processing and / or memory device is supplied, characterized in that in order to achieve sharp images from at least two surfaces or levels of different depths of the object, the same, avoiding an initial setting, further setting (s) or adjustment (s) - preferably at the same time - with light of at least two different and different from each other - at least in the we considerable - isolated wavelength ranges, in particular wavelength bands, and the images formed by the optical system - preferably after appropriate basic focusing - from the at least two depth positions of the object - at least essentially or preferably - are simultaneously imaged in an imaging surface, in particular plane and a direct observation and / or an observation, measurement value acquisition, recording, processing or processing and / or storage device. 2. The method according to claim 1, characterized in that the object to be examined and / or imaged with light from at least two mutually different and isolated wavebands from the Ultraviolet, visible and / or infrared range is applied. 3. The method according to claim 1 or 2, characterized in that the Object to be examined and / or imaged with light from at least one applied to two wavebands of different positions in the wavelength spectrum whose maximum positions are at least as far apart from one another are like the respective arithmetic mean of the sum of their Half widths is. 4. The method according to any one of claims 1 to 3, characterized characterizes that the object to be examined and / or to be imaged with light in each case at least two wavebands of different positions in the wavelength spectrum is applied, which each other, on the power or energy of the individual band, by a maximum of 20%, preferably by a maximum of 10% overlap.   5. The method according to any one of claims 1 to 4, characterized characterizes that the object to be examined and / or to be imaged with light in each case at least two wavebands of different positions in the wavelength spectrum is applied, the half-widths of each 2 to 25 nm, preferably 2 to 10 nm, in particular 3 to 5 nm. 6. The method according to any one of claims 1 to 5, characterized characterizes that the object to be examined and / or to be imaged with light in each case at least two wavebands of different positions in the wavelength spectrum is applied in terms of its spatial homogeneity is optimized in each case. 7. The method according to any one of claims 1 to 6, characterized characterizes that the object to be examined and / or to be imaged with light each have at least two wavebands in different positions Wavelength spectrum is applied, which is at least two different spectral band-specific light emitters, in particular LED and / or Laser diode and / or gas discharge emitters, originated. 8. The method according to any one of claims 1 to 7, characterized characterizes that the object to be examined and / or to be imaged with light each have at least two wavebands in different positions Wavelength spectrum is applied, which be a plurality of the object and / or single light sources radiating geometrically uniformly order around the optical axis and / or at least two concentrically around the arranged in the optical axis, ring-like or toroidal light emitters. 9. The method according to any one of claims 1 to 8, characterized characterizes that the object to be examined and / or to be imaged with light a plurality of mutually isolated spectral bands is applied, the respective individual intensities, preferably computer-aided control, to one another compared and / or to the spectral characteristic of the optical, in particular microscope-optical, system and / or the image receiving and recording device device, in particular video sensor, CCD sensor and / or image converter, adapted will. 10. The method according to any one of claims 1 to 9, characterized records that an image receiving and recording device, especially video sensor and / or image converter, preferably optoelectronic image converter, is used which at least in the respective spectral range of the light of two different, separate spectral bands producing Light emitter uniform and / or the spectral characteristic of the optical, especially adapted microscope-optical, system and / or the light emitter  or has adaptation-controllable conversion characteristics. 11. The method according to any one of claims 1 to 10, characterized records that by means of the video sensor and / or image converter downstream image processing and processing and / or playback device, that of individual components or of the overall system of Multi-spectral band light emitters, object, optics and / or image reception and Recording device-generated pixel intensity and / or spectral Transmission errors by means of, preferably computer-aided, control device be balanced. 12. The method according to any one of claims 1 to 11, characterized records that by means of the image receiving and recording device subordinate image conversion setup, processing and / or processing device, which are simultaneously isolated from each other by light from a plurality of Spectral bands generated images from a corresponding plurality of Depth of the object of an object to be examined and / or depicted jectes as a three-dimensional image of the same in the image reproduction and / or storage device is introduced and output by the same and / or is saved. 13. A device, in particular a microscope or the like, for detecting, measuring, observing and / or imaging objects, in particular small dimensions, with increased depth of field, in particular for carrying out a method according to one of claims 1 to 12, characterized in that that essentially around the objective section and / or below the object table ( 10 ) of a, preferably optically corrected, microscope ( 1 ) at least one, preferably ring-like, light emitter carrier body ( 20 ) with at least two groups of to the object table or to be examined and / or object to be imaged directed light from at least two narrow spectral band light emitters ( 2 , 2 'or S1, S2, S3) which emit or produce at least essentially isolated wavelength bands, in particular LED, laser diodes and / or gas discharge lamps , which are preferably adjustable in intensity. 14. Device, in particular microscope, according to claim 13, characterized in that in the imaging plane of the microscope ( 1 ) the image receiving surface ( 30 ) of a video sensor and / or image converter is arranged, which at least one, preferably computer-aided, image conversion, up, processing and / or processing and / or playback and storage device ( 4 ) is assigned or subordinated. 15. A device, in particular microscope, according to claim 13 or 14, characterized in that the light emitters ( 2 , 2 'or S1, S2, S3) of each group of spectral bands in preferably angular positions on at least one circle or on a plurality of concentric one another Circles are arranged on the carrier body ( 20 ) or in recesses thereof. 16. Device, in particular microscope, according to one of claims 13 to 15, characterized in that from a single light emitter ( 2, 2 '; S1, S2, S3) each have a spectral band, several light guides and whose light emission ends at the points of a plurality or Group of light emitters are also arranged in each case with the same spectral bands. 17. The method according to any one of claims 1 to 12, characterized records that the individual images of each of a given spectral band corresponding levels in the different depths of the to be examined and / or object to be imaged by sequential light exposure or Illumination and / or sequential scanning or the like on the recording sensor surface of the video sensor or the like. Recorded and / or stored sequentially individually and these single images of the different depth levels Image processing, processing and processing to a spatial (3D) view of one Image output and / or storage device is delivered.