RU2481602C1 - Dual-spectrum lens with discretely variable focal distance - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: lens consists of a fixed component having a first positive convex-concave lens, a second convex-concave lens and a third negative convex-concave lens, and a movable component having a first lens, a second convex-concave lens and an additional third positive convex-concave lens. The focal distance is changed by moving the fixed component between the second and third lenses of the fixed component into and out of the optical channel. In the fixed component, the second lens is positive and in the movable component, the first lens is convex-concave and negative, and the second lens is positive.

EFFECT: high energy capacity of the lens.

7 cl, 1 dwg

Description

The invention relates to infrared optical systems and can be used in thermal imagers.

In thermal imagers, lenses with different characteristics are used: with discretely and smoothly variable focal length, operating in the same spectral range (see patents RU 2183342 C1, publ. 10.06.2002, RU 2321873 C1, publ. 10.04.2008); with a constant focal length, operating in two spectral ranges (see patent US 6423969 B1, publ. 23.07.2002).

мм, при его выведении -

мм, кратность изменения фокусного расстояния

составляет 2,86. Указанный объектив формирует изображение в одной фокальной плоскости в двух спектральных диапазонах: 3,7-4,7 мкм и 8,1-8,7 мкм, при этом в неподвижном компоненте первая и четвертая линзы выполнены из селенида цинка (ZnSe), вторая и третья линзы - из фтористого бария (BaF₂), положительная линза подвижного компонента - из AMTIR1, отрицательная линза подвижного компонента - из мышьяковистого трехсернистого стекла (As₂S₃).The closest in technical essence to the claimed lens adopted for the prototype is a two-spectral infrared lens with a discretely variable focal length (see patent US 2005/0243411 A1, IPC ⁷ G02B 21/36, publ. 03.11.2005), consisting of a fixed component containing a first convex-concave positive lens, a second biconcave negative lens, a third convex-concave negative lens and a fourth biconvex positive lens, and a movable component containing a convex-concave positive lens and concave-convex negative lens. In addition, in the stationary component, the first surface of the first lens and the first surface of the fourth lens are aspherical, the lens of the movable component also contains two aspherical surfaces. Changing the focal length of the lens is carried out by introducing into the optical path and removing from it a moving component in the space between the second and third lenses of the stationary component. With the introduction of the moving component, the focal length of the lens

mm, when removing it -

mm, focal length change ratio

is 2.86. The specified lens forms an image in one focal plane in two spectral ranges: 3.7-4.7 μm and 8.1-8.7 μm, while in the stationary component the first and fourth lenses are made of zinc selenide (ZnSe), the second and the third lens is from barium fluoride (BaF ₂ ), the positive lens of the moving component is from AMTIR1, the negative lens of the moving component is from arsenic tri-sulphurous glass (As ₂ S ₃ ).

The length of the lens (L) from the first surface to the image plane is 229 mm, while the ratio

The disadvantage of this infrared lens is a small relative aperture (the ratio of the diameter of the entrance pupil to the magnitude of the focal length) - 1: 5.3, which determines the lens aperture and affects its energy ability. With such a small relative aperture, a small radiation flux from the objects of observation enters the photodetector of the thermal imager, which significantly reduces the range of the device.

The problem to which the invention is directed, is to increase the energy ability of a two-spectral infrared lens with a discretely variable focal length.

This goal is achieved by the fact that in a two-spectral infrared lens with a discretely variable focal length, consisting of a fixed component containing a first positive convex-concave lens, a second convex-concave lens and a third convex-concave negative lens, and a movable component containing the first lens and the second concave-convex lens, and the change in the focal length of the lens is carried out by introducing into the optical path and removing from it a moving component in the space between Ora and third fixed lens component, a fixed second lens component is made positive, while the movable component is introduced third additional convexo-concave positive lens, the first lens is formed concavo-convex, negative, and positive second lens is formed.

And also by the fact that in the stationary component on the first surface of the second lens a binary microrelief is made.

And also the fact that the binary microrelief changes the phase of the wavefront in accordance with the expression:

φ = -64.90383ρ ² -2.08826ρ ⁴ ,

where φ is the phase of the wave front;

ρ is the normalized radial coordinate of the surface aperture.

And also the fact that in the moving component on the first surface of the sixth lens a binary microrelief is made.

And also the fact that the binary microrelief changes the phase of the wavefront in accordance with the expression:

φ = -25.10108ρ ² -1.32959ρ ⁴ ,

where φ is the phase of the wave front;

ρ is the normalized radial coordinate of the surface aperture.

And also by the fact that in the stationary component, the first surface of the third lens is aspherical.

And also the fact that in the stationary component the aspherical surface of the third lens is made in accordance with the equation:

y ² + z ² = 153.78x + 0.1171x ² ,

where y is the axis of the coordinate system lying in the plane of the meridional section of the lens;

z is the axis of the coordinate system lying in the plane of the sagittal section of the lens;

x is the axis of the coordinate system that coincides with the optical axis of the lens.

мм и

мм) с расположением компонентов, соответствующим минимальному фокусному расстоянию.The drawing shows an optical diagram of a two-spectral infrared lens with a discretely variable focal length (

mm and

mm) with an arrangement of components corresponding to the minimum focal length.

A two-spectral infrared lens with a discretely variable focal length consists of a fixed component located along the optical axis containing the first positive convex-concave lens 1, the second positive convex-concave lens 2 and the third negative convex-concave lens 3, and the movable component containing the first negative concave -convex lens 4, the second positive concave-convex lens 5 and the third positive convex-concave lens 6. Change the focal length of the lens etsya introduction into the optical path and elimination therefrom of the movable component within the space between the second 2 and third 3 of the fixed component lenses.

The design parameters of the lens are shown in table 1.

Table 1 Lens number Radius of a spherical surface, mm Axial thickness, mm Material one r ₁ = 196.32 d ₁ = 10 Germanium r ₂ = 207.43 ¹⁾ d ₂ = 10 2 r ₃ = 136.51 ²⁾ d ₃ = 10 Zinc Selenide r ₄ = 199.2 d ₄ = 20 four r ₅ = -185.75 d ₅ = 5 Germanium R ₆ = -455.67 d ₆ = 77 5 r ₇ = -1354.43 d ₇ = 5 Germanium r ₈ = -259.83 d ₈ = 8 6 r ₉ = 41.69 ³⁾ d ₉ = 5 Zinc Selenide r ₁₀ = 48.05 d ₁₀ = 25 3 r ₁₁ = 76.89 ⁴⁾ d ₁₁ = 5 Germanium r ₁₂ = 71.62 ¹⁾ - an aspherical surface of the form: y ² + z ² = 416.86x-1.1253x ² ; ²⁾ - binary microrelief: φ = -64.90383ρ ² -2.08826ρ ⁴ ; ³⁾ - binary microrelief: φ = -25.10108ρ ² -1.32959ρ ⁴ ; ⁴⁾ is an aspherical surface of the form: y ² + z ² = 153.78x + 0.1171x ² .

As can be seen from the table, the objective lenses are made of two optical materials: germanium and zinc selenide. The combination of these materials, the choice of optical forces and the shape of the lenses, as well as the execution of the binary type microrelief on the two indicated surfaces provide the correction of chromatic aberrations in two spectral ranges: 3-5 and 8-12 microns.

A two-spectral infrared lens with a discretely variable focal length works as follows: a parallel beam of infrared rays passes through all the lenses of the lens, refracted on each surface in accordance with the radii and materials of the lenses and focuses on the optical axis in the focal plane. Inclined beams of rays also pass through all the lenses of the lens and focus accordingly at other points in the focal plane.

мм), или выведением этого компонента из оптического тракта (при такой конфигурации

мм).The focal length of the lens is changed by introducing into the optical path a movable component containing lenses 4, 5 and 6 (with this configuration

mm), or by removing this component from the optical path (with this configuration

mm).

составляет 1,075.The lens is designed to operate in two spectral ranges: 3-5 and 8-12 microns, with two optical materials used: germanium and zinc selenide. The relative aperture of the lens is 1: 2, the length (L) from the first surface to the image plane is 215 mm, the ratio

is 1,075.

Thus, the implementation of a two-spectral infrared lens with a discretely variable focal length in accordance with the formula of the claimed materials allows to increase its energy characteristics by increasing the relative aperture from 1: 5.3 to 1: 2 while maintaining the focal length change ratio M = 2.86.

Claims (7)

1. A two-spectrum infrared lens with a discretely variable focal length, consisting of a fixed component containing a first positive convex-concave lens, a second convex-concave lens and a third convex-concave negative lens, and a movable component containing a first lens and a second concave-convex lens moreover, changing the focal length of the lens is carried out by introducing into the optical path and removing from it a movable component in the space between the second and third lenses of the stationary component, characterized in that in the fixed component the second lens is made positive, and in the movable component a third additional convex-concave positive lens is introduced, the first lens is concave-convex, negative, and the second lens is made positive. 2. The lens according to claim 1, characterized in that in the stationary component on the first surface of the second positive convex-concave lens, a binary microrelief is made. 3. The lens according to claim 2, characterized in that the binary microrelief changes the phase of the wavefront in accordance with the expression
φ = -64.90383ρ ² -2.08826ρ ⁴ ,
where φ is the phase of the wavefront;
ρ is the normalized radial coordinate of the surface aperture. 4. The lens according to claim 1, characterized in that the binary microrelief is made in the movable component on the first surface of the third positive convex-concave lens. 5. The lens according to claim 4, characterized in that the binary microrelief changes the phase of the wavefront in accordance with the expression
φ = -25.10108ρ ² -1.32959ρ ⁴ ,
where φ is the phase of the wavefront;
ρ is the normalized radial coordinate of the surface aperture. 6. The lens according to claim 1, characterized in that in the stationary component, the first surface of the third negative convex-concave lens is aspherical. 7. The lens according to claim 6, characterized in that in the stationary component the aspherical surface of the third lens is made in accordance with the equation
y ² + z ² = 153.78x + 0.1171x ² ,
where y is the axis of the coordinate system lying in the plane of the meridional section of the lens;
z is the axis of the coordinate system lying in the plane of the sagittal section of the lens;
x is the axis of the coordinate system that coincides with the optical axis of the lens.