RU2607842C1 - Macro lens with variable magnification - Google Patents

Abstract

FIELD: optics.

SUBSTANCE: lens has four groups of lenses. First and fourth groups are fixed and have positive optical power. Second and third groups have negative and positive optical power and can be moved. First group is made of single biconvex lens, gluing of biconvex lens and negative meniscus, facing object, and single negative meniscus, facing image. Second group is made of gluing of biconvex and biconcave lenses and second single biconcave lens. Third group is made of single biconvex lens and negative meniscus, convex side of which faces image. Fourth group includes front component of biconvex lens, glued with negative meniscus, convex side faces image, and rear component of meniscus in form of positive and negative menisci are glued together, convex side of which faces object, and single positive meniscus, convex side of which faces object.

EFFECT: technical result is high image quality in whole range of focal distance during capture with distances comparable with focal distance of lens.

1 cl, 8 dwg, 1 tbl

Description

The invention can be used in photo and video systems where it is necessary to shoot objects from a short distance, comparable to the focal length of the lens, and with the possibility of a smooth change in magnification, for example, in medical equipment.

The known zoom lens described in RF patent No. 2545064, IPC G02B 15/16, contains four components and an aperture diaphragm located in front of the fourth component. The first and fourth components are positive, the second and third are negative and are mounted with the possibility of movement along the optical axis. The first component contains a positive lens glued from a negative meniscus and a biconvex lens, a biconvex lens and a positive meniscus. The second component contains a negative meniscus, a biconcave lens, and a positive meniscus. The third component is negative and glued from a positive meniscus and a biconcave lens. The fourth component contains a double-glued biconvex and biconcave lens, a positive meniscus, a negative meniscus, a biconvex lens, two negative meniscus and a biconvex lens. But this lens is not intended for macro photography and its working spectral region is 680-820 nm.

Closest to the present invention is a zoom lens described in US patent No. 4233981, NPK 350/184, IPC G02B 15/16, publ. September 23, 1980, which consists of four lens groups. The first lens group has a positive optical power and provides focusing of the lens by moving it along the optical axis. The second movable lens group, which has negative optical power, provides a change in focal length. The third movable lens group, which has a positive optical power, moving according to a nonlinear law simultaneously with the second lens group, provides an unchanged position of the image plane when changing the focal length of the lens. In this case, moving 1-3 lens groups form an afocal system for a relatively infinitely distant object. The fourth lens group is a projection one and includes the front component, consisting of positive and negative lenses, and the rear component, consisting of the meniscus, convex to the image plane, and the positive lens. At the same time, this lens has a relatively low image quality, which does not allow its use for macro photography and for shooting with high-resolution digital matrices.

The objective of the invention is to increase the operational characteristics and image quality over the entire range of the focal length.

The technical result is the creation of a macro lens with variable magnification and high image quality over the entire range of focal lengths of at least 4 times when shooting from a finite distance comparable to the focus of the lens, which makes it possible to use high-resolution matrices with a small pixel size for image registration.

This is achieved by the fact that in a macro lens with a variable magnification containing four groups of lenses, the fourth group is stationary, and the second and third are mounted with the ability to move along the optical axis when changing the focal length, the first group of lenses made with positive optical power from sequentially installed along the beam front single biconvex lens and gluing containing biconvex and negative lenses, the second movable group is made with negative optical power from gluing for of a ovaconvex and first biconcave lenses and a second biconcave lens, the third mobile group is made with positive optical power from positive and negative lenses, the fourth stationary group is made with positive optical power and includes front and rear components, while the front one is made of negative and positive lenses, and the back is made of a meniscus and a single positive lens, in contrast to the known first group of lenses is fixed, the negative lens is located in the first gluing, made I’m in the form of a meniscus and convex to the plane of objects, pasting one single negative meniscus, convex side to the image plane, in the second group of lenses the second biconcave lens is single, in the third component the lenses are single, the first of which is biconvex, and the negative one is made a meniscus with a convex side facing the image plane, in the fourth group of lenses in the front component of the first is a biconvex lens glued with a negative meniscus, the convex side to the image plane, in the rear component the meniscus is made in the form of gluing the positive and negative menisci, convex to the plane of objects, a single positive lens is made in the form of a meniscus, convex side to the plane of objects, and the lens aperture diaphragm is located between the front and the rear components of the fourth group of lenses, while the following conditions are met:

1.8 <f1 / f4 <2.2,

where: f1 and f4 are the focal lengths of the first and fourth fixed lens groups, respectively;

-4.2 <f11 / f14 <-2.2,

where: f11 is the focal length of the anterior single biconvex lens of the first group of lenses;

f14 is the focal length of the added negative meniscus of the first group of lenses, convex side facing the image plane.

The proposed solution is illustrated by the following graphic materials.

FIG. 1. Optical design of a macro lens with variable magnification in the long focus position.

FIG. 2. Optical design of a macro lens with variable magnification in the short focus position.

FIG. 3. Frequency-contrast characteristic (FM) of a macro lens with variable magnification in the position of long focus.

FIG. 4. Frequency-contrast characteristic (FM) of a macro lens with variable magnification in the position of the intermediate focus.

FIG. 5. Frequency-contrast characteristic (FM) of a macro lens with variable magnification in the short-focus position.

FIG. 6. Schedule of distortion of a macro lens with a variable increase in the position of long focus.

FIG. 7. The graph of the distortion of a macro lens with a variable increase in the position of the intermediate focus.

FIG. 8. The graph of the distortion of a macro lens with a variable increase in the position of short focus.

A variable zoom macro lens (Fig. 1) contains four lens groups, of which the first and fourth groups are fixed, and the focal lengths of the first f1 and fourth f4 fixed groups of lenses satisfy the following relations: 1.8 <f1 / f4 <2.2, and the second and third along the optical axis when changing the focal length. The first fixed group of lenses has positive optical power and consists of a front single biconvex lens 1, gluing a negative meniscus 2, convex side to the plane of objects, and a biconvex lens 3, and added a single negative meniscus 4, convex side to the image plane, with the focal the distance f11 of the front single biconvex lens 1 of the first group of lenses and the focal length f14 of the added negative meniscus 4 of the first group of lenses is convex first side to the image plane, satisfy the following relationships: -4.2 <f11 / f14 <-2.2. The second mobile group has negative optical power and consists of gluing a biconvex lens 5 and a first biconcave lens 6, as well as a second single biconcave lens 7. The third mobile group has a positive optical power and consists of a single biconvex lens 8 and a negative meniscus 9 facing the convex side to the image plane. The fourth stationary group has a positive optical power and consists of a front component made in the form of gluing a biconvex lens 10 and a negative meniscus 11 facing the convex side to the image plane, and a rear component made in the form of gluing the positive meniscus 12 and the negative meniscus 13 convex side to the plane of objects, as well as a single positive meniscus 14, convex side to the plane of objects. Between the front and rear components is the aperture diaphragm of the lens.

In FIG. 2 shows an optical diagram of a macro lens with variable magnification in the short focus position.

The macro lens works as follows: in the short focus position of 50 mm, the second and third mobile lens groups are located near the first fixed lens group. To increase the focal length, the second and third groups of lenses move toward the fourth stationary group of lenses. In this case, the second group of lenses moves according to a linear law. The third group of lenses moves according to a nonlinear law, but the change in the distance between the second and third groups during the movement is small. In the position of long focus, the second and third groups of lenses are located near the fourth stationary group of lenses. For refocusing, all four groups of lenses as a whole move relative to the plane of the array image sensor (not shown).

. КПМ объектива на пространственной частоте 80 лин/мм составляет не менее 0.5 по оси и не менее 0.3 по полю на всех фокусных расстояниях, таким образом, имеется возможность использования для регистрации изображения матриц высокого разрешения с малым размером пиксела.The introduction of an additional lens (fourth) in the form of an added single negative meniscus in the first lens group, as well as the use of a special low-dispersed grade of OK4 glass in the front single biconvex lens, significantly improved the correction of spherical and chromatic aberrations and, as a result, significantly increased spatial resolution compared with the closest analogue. In the third lens group in a single biconvex lens, low-dispersion glass of the OK4 type is also used, which allows one to minimize chromatic aberrations when the focal length is changed and to achieve high resolution of the lens over the entire range of focal lengths. A significant difference in the thermal expansion coefficient of OK4 glass necessitated the sticking of lenses in the third lens group compared to the prototype. In the fourth lens group, the meniscus was replaced, convex to the image plane by gluing two meniscuses, convex to the plane of objects. This change also leads to improved lens performance. Thus, a technical result has been achieved, since this set of features allows you to create a macro lens with a focal length of 50-220 mm, designed for shooting at close range (200-500 mm). The spectral range of the lens is 400-700 nm, the field of view in the image space is 8 mm, i.e. corresponds to the size of the matrix

. The KPM of the lens at a spatial frequency of 80 lines / mm is not less than 0.5 along the axis and not less than 0.3 along the field at all focal lengths, so it is possible to use high-resolution image sensors with a small pixel size for image registration.

The lens parameters of the lens are shown in table 1

Claims (8)

A macro lens with variable magnification, containing four groups of lenses, the fourth of which is stationary, and the second and third are mounted with the ability to move along the optical axis when changing the focal length, the first group of lenses made with positive optical power from sequentially installed along the beam of the front single biconvex lens and gluing containing biconvex and negative lenses, the second movable group is made with negative optical power from gluing biconvex and first a biconcave lens and a second biconcave lens, the third mobile group is made with positive optical power from positive and negative lenses, the fourth stationary group is made with positive optical power and includes front and rear components, while the front one is made of negative and positive lenses, and the rear one is made of meniscus and a single positive lens, characterized in that the first group of lenses is fixed, in the gluing of the first there is a negative lens made in the form of a meniscus and convex to the plane of objects, after gluing, a single negative meniscus is added, convex to the image plane, in the second component the second biconcave lens is single, in the third component the lenses are single, the first of which is biconvex, and the negative one is made in the form of a meniscus with the convex side to the image plane, in the fourth group of lenses in the front component of the first there is a biconvex lens glued with a negative meniscus facing the convex side to the image plane, in the back component, the meniscus is made in the form of gluing the positive and negative menisci, convex side to the plane of objects, a single positive lens is made in the form of a meniscus, convex side to the plane of objects, and the aperture lens diaphragm is located between the gluings of the fourth component, when The following conditions are met: 1.8 <f1 / f4 <2.2, Where: f1 and f4 are the focal lengths of the first and fourth stationary components, respectively; -4.2 <f11 / f14 <-2.2, Where: f11 is the focal length of the anterior single biconvex lens of the first component; f14 is the focal length of the added negative meniscus of the first component, convex side facing the image plane.

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