RU120245U1 - PLANOCHROMATIC HIGH-APERTURE MICRO LENS - Google Patents

Abstract

1. Planapochromatic high-aperture microlens containing three components, the first of which I with optical power ФI is made in the form of a frontal meniscus facing the concavity of the object space, and a biconvex positive lens, the second component II with optical power ФII, consisting of glued positive and biconcave negative lenses, and the third component III with optical power ФIII, characterized in that in the second component II behind the glued lens, consisting of positive biconvex and biconcave negative lenses, a positive biconvex lens with optical power ФII5 and a glued lens with optical power ФII6 are placed along the beam path , 7, consisting of a negative meniscus facing the concavity of the image space and a positive biconvex lens, and the third component III is made in the form of a flat-convex positive lens and a glued meniscus facing the concavity of the object space and consisting of a positive and a negative meniscus, while the ratio of the optical power of the lenses ФII5,6,7 to the optical power of the lens as a whole FOB satisfies the condition:! 0.25≤ | ФII5.6.7 / Fob | ≤0.65, where; ; ! where f 'is the focal length, in addition, a positive biconvex lens with optical power ФII5 and a positive biconvex lens of a glued lens of the second component II with optical power ФII7 are made of a material with a dispersion coefficient satisfying the condition: 64 <νd <95.2, and a negative meniscus with optical power ФII6, facing the concavity to the image space of the bonded lens of the second component II, is made of a material with a dispersion coefficient satisfying

Description

The proposed utility model relates to optical instrumentation for visual and photographic observation and research of low-contrast microscopic structures that are at the limit of the resolution of light microscopes equipped with all modern methods of studying objects in natural light, in polarized light, in the light of visible luminescence, using bright field, dark field, phase contrast, etc.

A planochromatic microscope objective is known [1], which contains five components, the first of which is a negative meniscus facing a convex surface to the image, the second is a single biconvex lens, the third is an glued component containing two positive biconvex lenses, with a negative biconcave lens placed between them, the fourth the component is a single positive biconvex lens and the fifth component is a double-glued meniscus facing a convex surface.

The lens has high quality over the entire linear field of view (2y '= 25 mm), but its output aperture is not high enough (0.0187).

The closest technical solution to the proposed utility model is a planachromatic high aperture micro lens [2], which contains three components, the first of which is made in the form of a meniscus facing concavity to the object’s space and a biconvex positive lens, the second contains a biconvex positive and glued from a biconvex and biconcave lenses and the third component consists of two positive biconvex lenses.

The lens has a rather large input aperture (20 ^x 0.65), planned correction, but insufficiently corrected position chromaticity (lens - achromat) and magnification chromaticity (CID = 0.8%).

Modern microscope models are equipped not only with higher aperture planochromatic micro-lenses, which have improved correction of monochromatic and chromatic aberrations throughout the linear field of view, but also have a real aperture diaphragm plane that allows you to place elements for phase contrast, Hoffman modulation contrast and iris diaphragms to change the depth of field.

The main task, which the utility model aims to solve, is to increase the image information capacity as a result of correcting the image curvature and the chromatic difference of magnifications with increasing numerical aperture and linear field of view.

To solve this problem, we propose a planochromatic high-aperture micro lens, which, like the prototype, contains three components, the first of which I with the optical power Ф _{I is} made in the form of a front meniscus facing concavity to the space of the object and a biconvex positive lens, the second component II with optical the power of F _II , consists of a bonded positive and biconcave negative lenses, and the third component III is made with the optical power of F _III .

In contrast to the prototype, in the second component II behind the glued lens, consisting of a positive biconvex and biconcave negative lenses, a positive biconvex lens with optical power _{f II5} and a _bonded lens with optical power _{f II6.7} , consisting of a negative meniscus, are placed along the beam concavity to the space of the image and the positive biconvex lens, and the third component III is made in the form of a plano-convex positive lens and a glued meniscus facing the concavity to the space of the object and consisting of positive and negative menisci, the ratio of optical power lenses _II5,6,7 F to the optical power of the lens as a whole _of F satisfies the following condition:

0.25≤ | F _II5.6.7 / F _about | ≤0.65, where ; ; Where

f 'is the focal length, in addition, a positive biconvex lens with an optical power of _{II II5} and a positive biconvex lens of an glued lens of the second component II with an optical power of II _{II7 are} made of a material with a dispersion coefficient satisfying the condition: 64 <ν _d <95.2, and the negative meniscus with the optical power Ф _II6 , turned concavity to the image space of the glued lens of the second component II, is made of material with a dispersion coefficient that satisfies the condition: 45 <ν _d <60.

In addition, the frontal meniscus of the first component I is made of material with a dispersion coefficient of 42 <ν _d <48 and a refractive index of n _d ≥1.8, while the ratio of the optical forces of components I and II and the lens as a whole Φ _ob satisfies the condition: 0.9 ≤F _{I, II} / Ф _rev ≤1.5, and the optical forces of a positive plano-convex lens Ф _III8 and a glued meniscus of the third component Ф _III9.10 are connected by the following ratio:

0.45≤F _III8 / F _III9.10 ≤0.65, where ; ;

where f 'is the focal length.

The essence of the proposed utility model lies in the fact that such a planochromatic high-aperture micro-lens implementation made it possible to improve the correction of mono and chromatic aberrations of the axial and off-axis beams, due to which a planochromatic correction was achieved.

In addition, the aperture was increased and the real plane of the aperture diaphragm was introduced.

Thus, a technical result was achieved consisting in increasing the input aperture and achieving planochromatic correction and the presence of a real aperture diaphragm plane, which is necessary for studies using the phase contrast method, modulation contrast according to the Hoffman method, etc.

The proposed plano-chromatic high-aperture micro lens is illustrated by the drawing, which shows its optical scheme, as well as by the Appendix, which gives the design parameters of the optical system.

A planaprochromatic high-aperture micro lens contains three components, the first of which I, with optical power Ф _{I, is} made in the form of a front meniscus 1 facing concavity to the object’s space and a biconvex positive lens.

The second component II with optical power Ф _II , consists of a bonded positive 3 and biconcave negative 4 lenses, behind a glued lens 3, 4 a positive biconvex lens 5 with optical power Ф _II5 and a glued lens 6 and 7 with optical power Ф _{II6 are placed , 7} consisting of a negative meniscus 6, facing concavity to the image space and a positive biconvex lens 7.

The third component III with optical power Ф _{III is} made in the form of a plano-convex positive lens 8 and a glued meniscus facing concavity to the space of the object and consisting of positive 9 and negative 10 menisci, with the ratio of the optical power of the lens F _II5,6,7 to the optical power of the lens in general, F _about satisfies the condition:

0.25≤ | F _II5.6.7 / F _about | ≤0.65, where ; ;

f 'is the focal length, in addition, a positive biconvex lens with an optical power of _{II II5} and a positive biconvex lens of an glued lens of the second component with an optical power of _{II II7 are} made of a material with a dispersion coefficient satisfying the condition: 64 <ν _d <95.2, and the negative meniscus with optical power Ф _II6 , turned concavity to the image space of the glued lens of the second component, is made of material with a dispersion coefficient that satisfies the condition: 45 <ν _d <60.

The front meniscus component 1 made of a first material having a dispersion coefficient of 42 <ν _d <48 and a refractive index n _d ≥1,8, wherein the ratio of optical powers of components I and II and the lens as a whole satisfies the condition _of F: 0,9≤F _{I, II} / Ф _rev ≤1.5, and the optical forces of a positive plano-convex lens Ф _III8 and a glued meniscus of the third component Ф _III9.10 are connected by the following ratio:

0.45≤F _III8 / F _III9.10 ≤0.65, where ; ; where f 'is the focal length.

The proposed planochromatic high-aperture micro-lens works with a tube lens (f '= 160 mm) as follows.

The front meniscus 1, facing the concave surface of the object space, together with the biconvex lens 2, builds an enlarged imaginary image with moderate values of spherical aberration, coma, astigmatism, image curvature and significant chromaticity of magnification (HR).

The second component II projects the image of the object after the first component I with an additional increase in the front focal plane of the third component III, introducing negative spherical aberration, positive coma and astigmatism, partially compensating for the chromaticity of position and magnification, and creates an image of the entrance pupil, i.e. the actual position of the aperture diaphragm in the rear focal plane of the system, consisting of the first component I and the second component II.

The third component III projects the image of the object after components I and II to infinity, compensating for the residual spherical aberration, chromaticity of position and magnification, astigmatism and image curvature.

In accordance with the proposed technical solution, a planochromatic high-aperture micro-lens was calculated with a real aperture aperture plane of magnification 20 times, an input aperture of 0.7, and a linear field of view of 25 mm.

The lens has high image quality over the entire linear field of view 2y '= 25 mm, so the Strehl ratio is from 0.83 in the center to 0.22 at the edge of the field of view.

Such values of the Strehl number cause a high concentration of energy in the center of the diffraction spot of scattering, and, therefore, a high contrast of the image over the entire field of visual observation.

Chromatic difference in magnification in the lens of the CID ≤0.3%.

The calculation results are given in the appendix.

The focal length of the lens, mm 8.0 Input aperture 0.7 Linear field of view, mm 25.0 The position of the entrance pupil, mm Endless Image Diameter, mm 25.0

Thus, in the proposed planochromatic high-aperture micro lens, the image information capacity was increased as a result of correction of the image curvature and chromatic difference of magnifications with increasing numerical aperture and linear field of view, and a real aperture diaphragm plane was created, which is necessary for placing elements for phase contrast, Hoffman modulation contrast and iris apertures for increasing depth of field.

INFORMATION SOURCES

1. Russian Federation, patent for invention No. 1658114, IPC: G02B 21/02, publ. 06/23/1991 g.

2. Russian Federation, patent for utility model No. 37239, IPC: G02B 21/02, publ. 04/10/2004 - the prototype.

Claims (2)

1. Plano-chromatic high-aperture micro lens containing three components, the first of which I with optical power Ф _{I is} made in the form of a front meniscus facing concavity to the space of the object and a biconvex positive lens, the second component II with optical power Ф _II , consisting of glued positive and a biconcave negative lens, and a third component having an optical power III F _III, wherein in the second component II of a glued lens consisting of a positive biconvex and biconcave Neg negative-lenses arranged along the beam path biconvex positive lens having a refractive power F _II5 and cemented lenses with an optical power P _II6,7, consisting of a negative meniscus concavity facing the space image and a positive biconvex lens, and the third component III is formed as a plano-convex positive and a cemented lens of a meniscus facing concavity to the object space and consisting of a positive and a negative meniscus, wherein the ratio of optical power lenses _II5,6,7 F to the optical power of sites willow generally _about F satisfies the following condition: 0.25≤ | F _II5.6.7 / F _about | ≤0.65, where

;

; where f 'is the focal length, in addition, a positive biconvex lens with an optical power of _{II II5} and a positive biconvex lens of an glued lens of the second component II with an optical power of II _{II7 are} made of a material with a dispersion coefficient satisfying the condition: 64 <ν _d <95.2 and a negative meniscus with an optical power of Φ _II6 , facing concavity to the image space of the glued lens of the second component II, is made of a material with a dispersion coefficient satisfying the condition: 45 <ν _d <60. 2. The plano-chromatic high-aperture micro lens according to claim 1, characterized in that the front meniscus of the first component I is made of material with a dispersion coefficient of 42 <ν _d <48 and a refractive index of n _d ≥1.8, and the ratio of the optical forces of components I and II and lens as a whole satisfies the condition _of F: 0,9≤F _{I, II} / F _of ≤1,5, and the optical power P of positive plano-convex lens and a cemented meniscus _III8 third component _III9,10 F are related as follows: 0.45≤F _III8 / F _III9.10 ≤0.65, where

;

, where f 'is the focal length.