DE102008006826A1 - Microscope objective i.e. oil immersion objective, for use in confocal microscope for compensating e.g. chromatic aberration, has adjusting device changing distances between lenses/lens groups to influence longitudinal chromatic aberration - Google Patents

Abstract

The invention relates to a microscope objective, which consists of a plurality of optical lenses (L1 to L13), which are partially combined into lens groups, and which is provided with an adjusting device for changing distances (A2, A3, A4, A6) between certain lenses (L1 to L13) or lens groups.
According to the invention the adjusting device is designed to change the distance of one or more distances, the
- influence on the longitudinal chromatic aberration and / or
- Influence on the spherical error, the field coma or the alignment length of the microscope object have.

Description

The The invention relates to a microscope objective, which consists of several consists of optical lenses or lens groups and that with an adjusting device is provided for changing distances between the lenses or lens groups.

It Microscope lenses are known in which distances between Lenses or lens groups are varied to correct for aberrations, which have their cause in different cover glass thicknesses. It will be the aberrations are essentially corrected by influence on the opening error of the relevant microscope objective.

For example, in EP 0 660 942 B1 a microscope objective is described in which a correction mount is provided for the displacement of lenses or lens groups in order to adapt to different cover glass thicknesses and thereby to correct aberrations. By means arranged on the correction socket spring which engages in a groove which is incorporated in a separate, inner socket, predetermined distances are changed.

In US 5,940,220 A1 is described a microscope objective, which is also designed to correct the aberration, here the arrangement of a transparent body between the sample and the microscope objective is provided.

On the other hand are known from the prior art no microscope lenses, those with settings for correcting chromatic aberrations, also referred to as longitudinal chromatic aberration (CHL), are equipped.

low Color longitudinal errors are especially in the case of microscope objectives important, which are used in confocal microscopy, in particular namely with regard to fluorescence cross correlation. There are different colored preparations introduced into solutions and observed to determine whether there are particles within a volume at the same time, which are marked with different dyes.

The detectable by means of the confocal structure of a microscope ellipsoidal volume is very small. ensures the corresponding microscope system and thus also the microscope objective due to already small color longitudinal deviations between any wavelengths no longer a perfect overlay of the Confocal volume of the two dyes, is the evaluation and interpretation of drugs extremely difficult, partly not even possible.

The Possibility of color fine adjustment on the microscope objective is desirable for any two dyes compensate for the color longitudinal error to exactly "zero" to be able to.

at The prior art microscope objective is the chromatic Longitudinal aberration unchangeable and varies depending on Type of microscope objective for a more or less large one Fraction of the depth of field. This is usually true though for visual observations, but not for the Measuring method described above with the aid of fluorescence cross correlation sufficient.

From that the invention is based on the object, a microscope objective to create, with the compensation of residual errors in the microscope beam path is possible, in particular the compensation of chromatic aberrations or spherical errors.

• – die Stelleinrichtung zur Abstandsänderung eines oder mehrerer Abstände ausgebildet ist, die Einfluß auf den Farblängsfehler haben, und/oder
• – die Stelleinrichtung zur Abstandsänderung eines oder mehrerer Abstände ausgebildet ist, die Einfluß auf den sphärischen Fehler, die Feldkoma oder die Abgleichlänge des Mikroskopobjektivs haben.

This object is achieved with a microscope objective of the type described above, in which

• - The adjusting device is designed to change the distance of one or more distances, which have an influence on the longitudinal chromatic aberration, and / or
• - The adjusting device is designed to change the distance of one or more distances that have influence on the spherical error, the field coma or the adjustment length of the microscope objective.

The inventive solution is particular for microscope objectives with enlargements from 40 × to 100 × at correspondingly large numerical apertures (NA> 0.75) suitable, because this predominantly for the aforementioned Fluorescence technology can be used.

In front all come for the invention Solution also microscope objectives with oil, water or other immersion media, because with these still larger apertures can be achieved.

One significant advantage of the microscope objective according to the invention is that a not optimally adjusted excitation page can be compensated.

at Laboratory abutments for the purpose of microscopy in the research field often only a microscope lens with available ren Lenses from optic kits usually combined not available with any color longitudinal correction are. With the microscope objective according to the invention on the other hand offers the advantage of making an optimal adjustment to be able to.

Advantageous is the adjusting device for changing a single air gap formed, the influence on the longitudinal chromatic aberration Has. Alternatively, the adjusting device for change be formed of intervals, the influence on the spherical error, the field coma or the adjustment length to have.

In Of course, the concept of the invention is included also microscope lenses, where the adjusting device both to change the air clearance with influence on the longitudinal chromatic aberration as well as to change intervals with influence on the spherical error, the field coma or the adjustment length.

The Adjusting device advantageously has at least one of the optical Axis rotatable correction ring, which via gear members with movable in the direction of the optical axis lenses or Lens groups coupled, with the displacement of the Change distances.

The Gear elements can be exemplified in the form of a screw drive or be designed in the form of a cam gear.

The Microscope objective according to the invention is intended below will be explained in more detail with reference to.

1 shows an embodiment of the microscope objective according to the invention, designed as an oil immersion objective. In this regard, on the left side of the drawing, a preparation P under the cover glass as an object to be examined and an immersion medium I are indicated.

from Preparation P or viewed from the object plane forth the lens along the optical axis first a first lens group with positive focal length, consisting of two Lenses L1 and L2 cemented together. At a distance A1 follows a meniscus-shaped third lens L3 with positive Focal length. This is followed at a distance A2 a second, as a triple Kittglied executed lens group with positive focal length, consisting of a positive lens L4, a negative lens L5 and a positive lens L6. It follows at a distance A3 a third lens group with negative focal length, consisting of a negative lens L7, one positive lens L8 and another negative lens L9. This is followed by a fourth at a distance A4 Lens group consisting of a positive lens L10 and a negative lens L11. Finally follows at a distance A5 is a fifth lens group made as a cemented component with a positive focal length, consisting of a meniscus lens L12 with a positive focal length and a meniscus lens L13 with a negative focal length.

For example are the distances A2 to A4 and the distance A6 are by means a correction ring, which is not shown in the drawing, variable.

By way of example, the microscope objective according to the invention has the following design data: radius Thickness / distance n _d v _d plan cover glass 0,170 59.5 1,522 plan Immersion medium AA = 0.220 47.8 1,515 plan L1 0,577 70.4 1,487 -0.66895 L2 3,985 46.5 1,804 -3.5485 A1 = 0.040 -29.005 L3 3,575 55.9 1.651 -8.004 A2 (variable) 16,669 L4 7,000 77.0 1,529 -10,000 L5 1,300 44.5 1,613 16.909 L6 5,230 77.0 1,529 -16.196 A3 (variable) 23.882 L7 1,300 44.5 1,613 6.5423 L8 7,650 95.0 1,434 -10.593 L9 1,350 44.5 1,613 -199.53 A4 (variable) 7.8292 L10 5.890 77.0 1,529 -12.497 L11 1,150 61.3 1,589 6,043 A5 = 0.000 -11.14 L12 3,790 40.9 1,581 -5.0877 L13 1,100 61.3 1,589 -11.631 A6 (variable) plane surface tube lens follows at a distance of 126.5 mm with a focal length of 164.5 mm.

The Microscope lens has a numerical aperture NA = 1.3, the magnification is -40 with a field of view of 25.

With the adjusting device, the working distance AA and the distances A2 to A4 and the distance A6 are changed according to the following configuration rule: configuration instructions AA A2 A3 A4 A6 1 0.226 0,251 0.174 0.236 0.546 2 0,220 0.351 0,216 0.274 0.472 3 0.214 0,451 0.257 0.312 0,400

The longitudinal chromatic aberration resulting in the configuration specification 1 is shown in the diagram 2 seen.

Comparable show 3 the adjusting with the configuration rule 2 color longitudinal errors and 4 the adjusting with the configuration rule 3 color longitudinal error.

AA

working distance

L1 to L13

lenses

A1 to A6

distances

P

preparation

I

Immersion medium

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 0660942 B1 [0003]
• US 5940220 A1 [0004]

Claims (10)

Microscope lens consisting of several optical Lenses or lens groups and an adjusting device for change of distances between the lenses or lens groups, where - the Adjustment device for changing the distance of one or more Distances is formed, the influence on the longitudinal chromatic aberration have, and / or - The adjusting device for changing the distance one or more distances is formed, the influence on the spherical error, the field coma or the adjustment length of the microscope lens. Microscope objective according to claim 1, wherein the adjusting device designed to change a single air gap (a2) is that has influence on the color longitudinal error. Microscope objective according to claim 1, wherein the adjusting device to change three distances (A3, A4, A5) with Influence on the spherical error, the field coma or the adjustment length is formed. Microscope objective according to claim 2, wherein the adjusting device both for changing a single air clearance (A2) is formed, the influence on the longitudinal chromatic aberration has, as well as to the change of three further intervals (A3, A4, A5), the influence on the spherical Error, the field coma or the alignment length of the microscope objective to have. Microscope objective according to claim 1, executed as an immersion objective, preferably as an oil immersion objective. Microscope objective according to one of the preceding claims, seen from a preparation P or from the object plane along the optical axis consisting of: - one first lens group with positive focal length of two with each other cemented lenses L1 and L2, - a meniscus-shaped Lens L3 with lens surfaces whose centers of curvature object-side, and positive focal length, - one formed as a triple cemented member second lens group with positive focal length from a positive lens L4, a negative Lens L5 and a positive lens L6, - a third Negative focal length lens group from a negative lens L7, a positive lens L8 and another negative lens L9, A fourth lens group consisting of a positive lens L10 and a negative lens L11, and - one formed as a cemented fifth lens group of a Meniscus lens L12 with a positive focal length and a meniscus lens L13 with a negative focal length. Microscope objective according to claim 5, having the following construction data: radius Thickness / distance n _d v _d plan cover glass 0,170 59.5 1,522 plan Immersion medium 0,220 47.8 1,515 plan L1 0,577 70.4 1,487 -0.66895 L2 3,985 46.5 1,804 -3.5485 A1 = 0.040 -29.005 L3 3,575 55.9 1.651 -8.004 A2 (variable) 16,669 L4 7,000 77.0 1,529 -10,000 L5 1,300 44.5 1,613 16.909 L6 5,230 77.0 1,529 -16.196 A3 (variable) 23.882 L7 1,300 44.5 1,613 6.5423 L8 7,650 95.0 1,434 -10.593 L9 1,350 44.5 1,613 -199.53 A4 (variable) 7.8292 L10 5.890 77.0 1,529 -12.497 L11 1,150 61.3 1,589 6,043 A5 = 0.000 -11.14 L12 3,790 40.9 1,581 -5.0877 L13 1,100 61.3 1,589 -11.631 A6 (variable) plane surface tube lens follows at a distance of 126.5 mm with a focal length of 64.5 mm. Microscope objective according to one of the preceding claims with the following configuration rule for changing the distances: configuration instructions AA A2 A3 A4 A6 1 0.226 0,251 0.174 0.236 0.546 2 0,220 0.351 0,216 0.274 0.472 3 0.214 0,451 0.257 0.312 0,400 Microscope objective according to one of the preceding claims, wherein the adjusting device at least one about the optical axis has rotatable correction ring, via gear members Coupled with lenses or lens groups that are in the direction of optical axis are displaceable. Use of a microscope objective according to the claims 1 to 9 in a confocal microscope to compensate for residual errors in the microscope beam path.