SU1180824A1 - Microscope lens - Google Patents

Abstract

A MICROSCOPE LENS, consisting of five components, of which the first is a single negative meniscus facing with a concavity towards the object, the second is a meniscus facing with a concavity towards the object, the third two-fold lens, the fourth and fifth are glued components, characterized in that in order to expand the working spectrum while reducing chromatic aberrations and maintaining high image quality in monochromatic light, the sixth positive and seventh negative components are inserted into it, e in the form of meniscus, glued from positive and negative meniscus, facing concavity to the object, and the eighth component, executed in the form of a positive lens, glued from a double lens and positive meniscus, while the second component is glued from positive and negative meniscus; the fourth component is made negative and glued together with double-convex and double-convex lenses, the fifth component is made in the form of 9 positive meniscus, facing its concavity to the object and glued together from positive and negative menisci, the equivalent focal distance of the second, third and fourth components is the focal length of the lens, the first lens and the second, fourth, fifth 00, sixth, and second .sedmogo eighth lens components cx made of fluorite. N3

Description

The invention relates to optical instrumentation, in particular to optical systems for microscopy, and can be used in installations for measuring the optical transfer functions of optical systems.

The purpose of the invention is the expansion of the working region of the spectrum while reducing chromatic aberration and maintaining high image quality in monochromatic ··. <·; the light.

The drawing shows an optical diagram of the proposed lens relating to optical systems for * 5 microscopy.

The lens consists of eight lens components. Component 1 is made in the form of a negative meniscus facing concavity to the subject. 20 The negative component 2 is glued from the positive and negative menisci facing concavities to the subject. Component 3 is a biconvex lens. The negative component 25 4 consists of a biconvex lens glued to a biconcave lens. The positive components 5 and 6 and the negative component 7 are each of the positive meniscus glued together with the negative meniscus. In this case, all meniscus lenses are turned concave to the subject. The positive component 8 is glued from a biconvex lens and a positive concave-convex meniscus made, like the positive lenses of the glued components, from fluorite with a refractive index of 1.43385 and a dispersion coefficient of 95.14.

The selection of materials, the shape and relative position of the components and lenses in the components make it possible to calculate the lens based on the need to expand the working region of the spectrum while reducing chromatic aberrations and maintaining high image quality in monochromatic light. Thus, a combination of two double-glued components 2 and 4 with a biconvex lens 3 between them with an equivalent focal length equal to 0.35 of the focal length of the entire lens, in combination with the action of components 5-7, allows one to correct chromatic aberrations in the spectral region of 380-800 nm. Moreover, the selection of the parameters of components 3,4 and 7 provides a greater degree of correction of chromatic aberrations in the short-wavelength part of the spectrum, while the corresponding selection of the parameters of components 5 and 6 allows one to reduce the value of chromatic aberrations in the long-wavelength part of the spectral range. The resulting deterioration in image quality due to changes in spherical aberration, astigmatism and distortion is compensated by the selection of the parameters of components 1 and 2 with some change in the parameters of components 5 and 7. Negative values of the secondary spectrum and chromatic aberration of component 8 can reduce the residual values of these aberrations in the system to acceptable values . The required magnitude of the linear increase in the system is provided mainly by the existing selection of optical powers of components 1 and 8.

According to the proposed optical scheme, a microscope objective with a magnification of β - -10 ^x , a numerical aperture A = 0.65, a linear field in the space of objects 2u = 0.4 mm, and a working distance S ₁ = -0.31 mm was calculated. Within the entire linear field, high image quality is maintained, which is close to diffraction. The secondary spectrum in any range in the spectral region of 380-800 nm reaches a value of the order of 1 μm.

Claims (1)

MICROSCOPE LENS, consisting of five components, of which the first is a single negative meniscus facing concavity to the subject, the second is the meniscus facing concavity to the subject, the third is a biconvex lens, the fourth and fifth are glued components, characterized in that, in order to expand the working spectral region while reducing chromatic aberration and maintaining high image quality in mono 6 chromatic light, the sixth positive seventh negative component is introduced into it, made in the form of menisci glued from the positive and negative menisci facing concavity to the object, and the eighth component, made in the form of a positive lens glued from a biconvex lens and a positive meniscus, the second component is glued from the positive and negative menisci, the fourth is negative and glued from a biconvex and biconcave lenses, the fifth component is made in the form of a positive of the meniscus facing concavity to the object and glued from the positive and negative menisci, the equivalent focal length of the second, third and fourth Q components is 0.35 of the focal length of the lens, and the first lenses of the second, fourth, fifth, sixth, seventh and second the lens of the eighth component is made of fluorite.