RU2545064C2 - Variable focus lens - Google Patents

Abstract

FIELD: physics, video.

SUBSTANCE: invention can be used in video cameras with a CCD array. A variable focus lens comprises four components and an aperture diaphragm placed in front of the fourth component. The first and fourth components are positive, the second and third components are negative and are capable of moving along an optical axis. The first component comprises a positive lens, glued from a negative meniscus and a biconvex lens, a positive lens and a positive meniscus. The second component comprises a negative meniscus, a biconcave lens and a positive meniscus. The third component is negative and is glued from a positive meniscus and a biconcave lens. The fourth component comprises a double-glued lens from a biconvex and a biconcave lens, a positive meniscus, a negative meniscus, a biconvex lens, two negative menisci and a biconvex lens. Relationships given in the claim are satisfied.

EFFECT: wider field of view and reduced relative distortion while maintaining high image quality in the entire measurement range of focal distance of the variable focus lens, which is not less than 5,5 units.

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Description

The invention relates to optical instrumentation, namely to lenses with variable focal length, and can be used as a camera lens with image formation on a CCD.

Known zoom lens [1], containing five components, the first, fourth and fifth components are positive, and the second and third components are negative and mounted with the possibility of movement along the optical axis. The first component contains a positive two-glued lens and a positive meniscus facing a convex surface to the space of objects. The second component contains a single negative meniscus with a convex surface facing the space of objects, and a double-glued lens consisting of a biconcave lens and a positive meniscus. The third component is made in the form of a negative meniscus facing a convex surface to the image space. The fourth component contains two positive lenses. The fifth component contains two groups of lenses, the first group includes a positive lens, a negative meniscus facing a concave surface to the space of objects, and a positive meniscus facing a concave surface to a space of images, the second group of lenses contains a positive lens, a negative meniscus facing a concave surface to a space of images , and a positive lens.

The aperture diaphragm is located between the fourth and fifth components. This lens design provides an almost 8x zoom. The disadvantage of a zoom lens is the relatively low image quality over the entire field of view for the entire range of focal lengths (spherical aberration is 0.05 mm, astigmatism 0.13 mm, distortion of at least 3%).

Closest to the proposed invention according to the technical solution is a zoom lens [2], intended for use in video cameras with image formation on a CCD. The zoom lens contains four components, of which the first and fourth components are positive, and the second and third components are negative and mounted with the ability to move along the optical axis. The first component contains a positive lens glued from a negative meniscus and a biconvex lens, and a positive meniscus glued from a biconvex and biconcave lens. The second component contains two negative lenses, the second of which is glued from the negative and positive menisci, facing a concave surface to the image space. The third component is made in the form of a double-glued lens containing a positive meniscus facing a concave surface to the space of objects, and a biconcave lens. The fourth component contains two groups of lenses spaced at least half of the posterior focal segment, of which the first along the beam group includes a sequentially double-glued lens and two positive menisci facing concave surfaces to the image space, the second group contains a positive meniscus facing concave surface to the space of objects, and a positive double-glued lens. The aperture diaphragm is located in front of the fourth component. This lens design provides high image quality for a 2W field of view of no more than 21 °. The relative distortion for the maximum angle of the field of view reaches 2%. The disadvantage of the prototype is that its optical design does not allow to increase the field of view while maintaining high image quality.

The objective of the invention is to increase the field of view and reduce relative distortion while maintaining high image quality over the entire range of changes in the focal lengths of a zoom lens, at least 5.5 times.

The zoom lens contains four components and an aperture diaphragm located in front of the fourth component, the first and fourth components of which are positive and the second and third components are negative and mounted with the possibility of movement along the optical axis, while the first component contains a positive lens glued from a negative meniscus convex surface to the space of objects, and a biconvex lens, and a positive meniscus facing a convex surface to the space of objects, the second the component contains two negative lenses, one of which is biconcave, the other is a meniscus facing a convex surface to the space of objects, the third component is a negative lens glued from a positive meniscus facing a convex surface to the image space, and a biconcave lens, the fourth component contains four positive lenses, the first of which is double-glued, the second is a positive meniscus, convex surface facing the space of objects, in contrast t of the prototype, in the first component, a positive lens is inserted between the positive double-glued lens and the positive meniscus, the first negative lens of the second component is the meniscus, the second negative lens is the biconcave lens, after which the positive meniscus is introduced, with its convex surface facing the space of objects, the double-glued lens of the fourth component contains biconvex and biconcave lenses, between the second and third positive lenses introduced a negative meniscus, facing convex after the third positive lens made biconvex, two negative meniscuses are introduced, which face is convex to the image space, the fourth positive lens is biconvex, in the fourth component the distance between the second negative meniscus and the biconvex lens is at least 0.34 focal distance of the component ratio of the first focal lengths f _'1 and second f' ₂ components of the third f _'3 and second f' ₂ components, the first f _'1 and quat rtogo f _'four components are:

-2.4 <f ' ₁ / f' ₂ <-2.3

0.7 <f ' ₃ / f' ₂ <0.73

l, 7 <f ' ₁ / f' ₄ <1.8.

The introduction of an additional positive lens in the first component, as well as the introduction of an additional positive meniscus in the second component, allowed to increase the field of view compared with the prototype. The introduction of a negative meniscus between the second and third positive lenses of the fourth component, as well as two negative menisci after its third positive lens and the choice of the distance between the second negative meniscus and the fourth positive lens of at least 0.34 focal lengths of the fourth component, allowed to correct the relative distortion to no more than 0.8% in the entire range of changes in focal lengths, as well as correct spherical aberration with a large focal length. The construction of the second component and its displacement makes it possible to correct the field aberrations of wide inclined beams in the region of small focal lengths. The choice of the ratio of the focal lengths of the first and second components, the third and second components, the first and fourth components, satisfying the following ratios:

-2.4 <f ' ₁ / f' ₂ <-2.2

0.7 <f ' ₃ / f' ₂ <0.75

l, 7 <f ' ₁ / f' ₄ <1.8,

allowed to obtain the design of a zoom lens with a range of focal lengths of at least 5.8 times while maintaining high image quality.

The proposed zoom lens operates in the spectral range λ = (680 ... 820) nm, the focal length of the lens varies from 38.7 mm to 226.3 mm, the relative aperture is 1: 4. The angle of view 2W = 31 ° ... 5.4 °. The relative distortion in the entire range of changes in the angles of the field of view does not exceed 0.8%. Spherochromatic aberration does not exceed 0.016 mm, astigmatism is not more than 0.06 mm, aberrations of wide beams are not more than 0.018 mm in the entire range of focal length changes.

Figure 1 shows the optical scheme of the proposed zoom lens.

Figure 2 shows the design parameters of the zoom lens and the characteristics of the glasses, where R is the radius of curvature of the lens surfaces, D is the distance between the lens surfaces, n _e is the refractive index of the lens glasses for the line e (λ = 546 nm), v _e is the Abbe number for line e, f 'is the focal length of the zoom lens.

Figure 3 shows the graphs of relative distortion for the minimum and maximum focal lengths of a zoom lens.

Figure 4 shows a graph of the calculated polychromatic frequency-contrast characteristic (T) at a point on the axis for the focal length f '= 38.7 mm

Figure 5 shows a graph of the calculated polychromatic frequency-contrast characteristic (T) at a point on the edge of the field of view 2W = 31 ° for the focal length f '= 38.7 mm

Figure 6 shows a graph of the calculated polychromatic frequency-contrast characteristic (T) at a point on the axis for the focal length f '= 226.3 mm

Figure 7 shows a graph of the calculated polychromatic frequency-contrast characteristic (T) at a point on the edge of the field of view 2W / = 5.42 ° for the focal length f '= 38.7 mm

The frequency-contrast characteristics of the lens are calculated in accordance with the table of spectral efficiency coefficients of the actinic radiation flux given below.

λ, μm 680 725 766.5 775 820 FROM 0.1 0.8 one 0.8 0.1

The zoom lens (figure 1) consists of four components 1-4. Component 1 contains a positive lens glued from a negative meniscus 5, facing a convex surface to the space of objects, and a biconvex lens 6, a biconvex lens 7, a positive meniscus 8, facing a convex surface to the space of objects. Component 1 is positive and fixed and its focal length is 142.7 mm.

Component 2 contains a negative meniscus 9 facing a convex surface to the space of objects, a biconcave lens 10 and a positive meniscus 11 facing a convex surface to the space of objects. The focal length of the component is 60.9 mm. By moving along the optical axis of this component, a change in the focal length of the lens is achieved.

Component 3 is made in the form of a negative lens glued from a positive meniscus 12, facing a convex surface to the image space, and a biconcave lens 13. Its focal length is -43.8 mm. Moving along the optical axis of this component ensures the stillness of the image plane over the entire range of the focal lengths of the lens.

Component 4 comprises a first positive lens glued from a biconvex lens 14 and a biconcave lens 15, a second positive lens made in the form of a positive meniscus 16 facing a convex surface to the space of objects, a negative meniscus 17 facing a convex surface to the space of objects, a third positive lens, made by a biconvex lens 18, two negative menisci 19,20 facing a convex surface to the image space, the fourth positive lens made by a biconvex a clear lens 21. The distance between the negative meniscus 20 and the fourth positive lens 21 is 29.2 mm, which is 0.357 of the focal length of the fourth component. Component 4 is positive and motionless. The focal length of the component is 81.9 mm.

The focal lengths of the components are given for λ = 766.5 nm.

The aperture diaphragm is located in front of the fourth component. The working region of the spectrum (680 ... 820) nm is distinguished by a light filter 22.

In the position in which the second and third components occupy the leftmost position, the zoom lens has a minimum focal length of 38.8 mm. When moving component 2 to the right to component 3 at a distance of 49.1 mm, and component 3 to the right towards the stationary component 4 at a distance of 27.4 mm, the focal length of the lens gradually increases to 226.9 mm.

The choice of the ratio of the focal lengths of the first and second components equal to 2.34, the ratio of the focal lengths of the third and second components equal to 0.719, and the ratio of the focal lengths of the first and fourth components equal to 1.743 allowed us to obtain a zoom lens design with a focal length range of at least 5.8 times while maintaining high image quality, while the length of the lens from the first surface to the image plane is 279.9 mm, which is l, 23f ' _max , where f' _max is the maximum focus of the zoom lens.

The zoom lens has the following characteristics:

- focal length 38.83 ... 226.96 mm - relative hole 1: 4 ... 1: 4 - line of sight 2W = 31 ° ... 5 ° 22 '

With a focal length f '= 38.83 mm, spherical aberration is 0.005 mm, spherochromatism is not more than 0.02 mm, astigmatism is not more than 0.04 mm, relative distortion is not more than 0.5%.

With a focal length f = 226.96 mm, spherical aberration is not more than 0.005 mm, spherochromatism is not more than 0.015 mm, astigmatism is not more than 0.02 mm, relative distortion is not more than 0.6%. The aberration values are given in a single image plane.

Thus, the proposed zoom lens allows to obtain an increase in the field of view, decrease in relative distortion while maintaining high image quality over the entire range of changes in the focal lengths of the zoom lens, which is at least 5.8 times, compared with the prototype.

Information sources

1. US patent No. 5061051, publ. 1990, MKI G02B 15/00.

2. Patent BY No. 8411, publ. 2005, MKI G02B 15/16 (prototype).

Claims (1)

A zoom lens containing four components and an aperture diaphragm located in front of the fourth component, the first and fourth components of which are positive and the second and third components are negative and mounted with the possibility of movement along the optical axis, the first component contains a positive lens glued from a negative meniscus facing a convex surface to the space of objects, and a biconvex lens, and a positive meniscus facing a convex surface to the space of objects, sec the th component contains two negative lenses, one of which is biconcave, the other is a meniscus facing a convex surface to the space of objects, the third component is a negative lens glued from a positive meniscus facing a convex surface to the image space, and a biconcave lens, the fourth component contains four positive lenses, the first of which is double-glued, the second is a positive meniscus, convex surface facing the space of objects, distinguish This is due to the fact that in the first component, a positive lens is inserted between the positive double-glued lens and the positive meniscus, the first negative lens is the meniscus, the second negative lens is the biconcave lens, after which the positive meniscus is introduced, with its convex surface facing the space of objects, and the double-glued lens of the fourth component contains biconvex and biconcave lenses, between the second and third positive lenses introduced a negative meniscus, facing after the third positive lens, made biconvex, two negative meniscuses are introduced, the convex surface facing the image space, the fourth positive lens is biconvex, in the fourth component the distance between the second negative meniscus and the biconvex lens is at least 0.34 focal distance of the component ratio of the first focal lengths f _'1 and second f' ₂ components of the third f _'3 and second f' ₂ components, the first f _'1 and Odd ertogo f _'four components are:
-2.4 <f ' ₁ / f' ₂ <-2.3
0.7 <f ' ₃ / f' ₂ <0.73
1.7 <f ' ₁ / f' ₄ <1.8.

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