RU187815U1 - TWO-LIGHT LIGHT LENS FOR IR SPECTRUM - Google Patents

Abstract

The two-lens fast lens for the infrared region of the spectrum can be used in thermal imaging devices built on the basis of photodetector arrays that do not require cooling to cryogenic temperatures, which are sensitive in the spectral range from 8 μm to 14 μm. The lens contains two positive menisci facing concave surfaces to the image plane and made of germanium. The radii of curvature of the surfaces satisfy the relations: R ₁ = (1.2 ÷ 1.3) ƒ; R ₂ = (1.64 ÷ 2.0) ƒ; R ₃ = (0.85 ÷ 1.1) ƒ; R ₄ = (1.1 ÷ 1.4) ƒ, where R ₁ , R ₂ are the radii of curvature of the first and second surfaces of the first meniscus, respectively, R ₃ , R ₄ are the radii of curvature of the first and second surfaces of the second meniscus, respectively, ƒ '- focal length of the lens. All refractive surfaces are aspherical. The technical result is an increase in the relative aperture and range of the device, an increase in the linear size of the image, which makes it possible to fully realize the capabilities of modern matrices with a format of 640 × 480 pixels with a pixel size of 17 × 17 μm. 2 s.p. crystals, 3 ill., 1 tab.

Description

The utility model relates to the field of optical instrumentation, namely to lenses for the infrared (IR) region of the spectrum, and can be used in thermal imaging devices built on the basis of bolometric photodetector arrays that do not require cooling to cryogenic temperatures, sensitive in the spectral range from 8 to 14 microns.

The creation of new and improvement of well-known circuit solutions of infrared lenses is based on a combination of characteristics, which include increasing the diameters of the entrance pupils, relative openings, image quality on the axis and field, reducing mass and overall dimensions, etc. Since the radiation detectors used in thermal imaging devices have quite definite linear dimensions, then, when used with the same receiver, the focal length of the lens and the angular field are inversely related to tional dependence. The desire to increase the transmittance of the lens and its mass makes us look for circuit solutions for the lens optics with the least number of lenses. Known lenses for the infrared region of the spectrum, containing two lenses [Patent US 2010/0165455. Compact two-element infrared objective lens and IR or thermal sight for weapon hawing viewing optics [1]; Patent RU 262988 C1. High-aperture infrared lens. Priority 05/25/2016, publ. 09/04/2017 [2]]. The ratios between the radii of curvature of the surfaces declared in the said patents and the shape of the lenses correspond to the ranges of optical characteristics (focal length, relative aperture, field) for which they were found. Improving one or all of the characteristics simultaneously requires the search for new circuit solutions for lens optics.

The problem the device is aimed at is creating an optical system for a two-lens high-aperture lens with a relative aperture higher than 1: 1 for the IR spectral region for a thermal imaging device with high technical and operational characteristics, which provides the possibility of interfacing with modern matrix IR detectors in the range of 8-14 microns, format 640 × 480 pixels with a pixel size of 17 × 17 microns.

The inventive two-lens fast lenses for the infrared region of the spectrum have correlations between the radii of curvature of the surfaces of the lenses, the form of their execution, different from the lens devices according to the specified patents.

The disadvantage of the lens [1] is the small value of the relative aperture; the diameter of the entrance pupil is 1.5 times less than desired and the image quality on the axis and field of view is poor.

The closest analogue to the claimed device in technical essence is the lens for the infrared region of the spectrum [Patent RU 262988 C1. High-aperture infrared lens. Priority 05/25/2016, publ. 09/04/2017 [2]], which in terms of the combination of characteristics and the arrangement of the optical circuit is closest to the proposed lens. Its description and analysis of the shortcomings are given below.

The closest analogue contains two positive menisci, the second surface of the first meniscus is aspherical, the lenses are made of germanium and face the image plane with their concave surfaces, the meniscus radii of curvature satisfy the following relationships:

R ₁ = (1.04 ÷ 1.26) ƒ;

R ₂ = (1.03 ÷ 1.62) ƒ;

R ₃ = (0.5 ÷ 0.79) ƒ;

R ₄ = (0.59 ÷ 0.98) ƒ,

where R ₁ , R ₂ are the radii of curvature of the first and second surfaces of the first meniscus, respectively, R ₃ , R ₄ are the radii of curvature of the first and second surfaces of the second meniscus, respectively, ƒ 'is the focal length of the lens.

In an example of a specific embodiment of the closest analogue, a lens with a focal length of 30 mm, a relative aperture of 1: 1.1, an angular field of 12.4 ° × 9.4 ° (diagonal of 15.5 °) is given. The value of the frequency-contrast characteristic (TSC) at a frequency of 30 lines / mm is 0.54 rel. units for the point of view on the axis and 0.36 rel. units - for the extreme point of the field of view (on the largest side of the matrix without taking into account the diagonal size). Distortion does not exceed - 1.3% in the field of view.

The disadvantages of the closest analogue include the following: a low relative aperture, a small linear size in the plane of the image of the lens, which does not fully realize the capabilities of modern matrices with a format of 640 × 480 pixels, a pixel size of 17 × 17 μm.

The ratio between the radii of curvature of the lenses in the closest analogue is such that when the relative aperture is increased to 1: 0.9, the image quality decreases and does not allow to provide the required values of the frequency-contrast characteristic.

The technical result achieved in solving this problem is to increase the relative aperture, which provides, respectively, an increase in the range of the device, an increase in the linear image size in the image plane of the lens, which makes it possible to fully realize the capabilities of modern matrices with a format of 640 × 480 pixels with a size pixels 17 × 17 microns.

The problem is solved, and the technical result is achieved by the fact that, in contrast to the closest analogue in the proposed device, a two-lens fast lens for the infrared region of the spectrum, the radii of curvature of the surfaces satisfy the following relationships:

where R ₁ , R ₂ are the radii of curvature of the first and second surfaces of the first meniscus, respectively, R ₃ , R ₄ are the radii of curvature of the first and second surfaces of the second meniscus, ƒ 'is the focal length of the lens, while the first surface of the first meniscus and both refracting surfaces the second meniscus are aspherical.

In a particular case, the lens is arranged to move along the optical axis. In a particular case, the lens is configured to move the second meniscus along the optical axis.

The proposed solution, in our opinion, is novel and is industrially applicable. All lenses of the lens are made using aspherical refractive surfaces, which is currently widely used in optical industrial technology in the development of competitive devices with high technical characteristics, made of a material whose technology for the manufacture of lenses for the infrared region of the spectrum is known and worked out at enterprises, specializing in the production of thermal imaging devices and their elements. At the same time, the authors are not aware of the optical schemes of lenses for the infrared region of the spectrum in which a combination of these features would be implemented.

The proposed device is illustrated by the following graphic materials:

FIG. 1 is an optical diagram of a two-lens fast lens for the infrared region of the spectrum;

FIG. 2 - graphs of frequency response for various points of the field of view;

FIG. 3 is a graph of distortion.

The optical system of the fast aperture lens for the infrared region of the spectrum (Fig. 1) contains two positive meniscus 1,2 facing concave surfaces to the image plane, all surfaces of which are aspherical, and located relative to each other at a distance of at least 0.9 0 ', this meniscus is made of germanium, transmitting radiation in the wavelength range of 8-14 microns. The radii of curvature of the lens surfaces 1, 2 satisfy relations (1).

In special cases, either the entire lens is arranged to move menisci together along the optical axis, or the second lens meniscus is mounted to move along the optical axis.

The implementation of the device is as follows. Lenses 1, 2 focus IR radiation coming from each point of distant objects within the angular field determined by the size of the matrix detector of IR radiation and the focal length of the lens, and create real images of objects in the image plane with which the receiving plane of the bolometric matrix radiation detector is aligned. The lens provides for each point of the object the focus of radiation in the spectral range, determined by the spectral sensitivity of the matrix of the receiving device, into a small spot that provides high values of contrast transmission coefficients for spatial frequencies corresponding to modern infrared radiation receivers with a format of 640 × 480 pixels (pixel size 17 × 17 μm).

To focus radiation coming from objects located at a finite distance from the lens, or to compensate for thermal defocusing due to the lens being used at temperatures different from the assembly temperature, in particular cases the whole lens can move, or the meniscus 2 can move, with the position of the first the meniscus and the image plane, combined with the plane of the infrared receiver, remains unchanged. In all special cases, the claimed image quality is maintained.

Table 1 shows the values of the radii of curvature, materials, the distances between the lenses of the lens and their diameters in a specific example of the performance of a fast lens for the infrared region of the spectrum. The values of the parameters are given when normalizing the focal length ƒ '= 1.

As follows from table 1, the radii of curvature of the lenses 1, 2 are related as follows: R ₁ : R ₂ : R ₃ : R ₄ = 1.21: 1.66: 1.0: 1.21, and satisfy relations (1). All four refracting meniscus surfaces are aspherical in the form of axisymmetric polynomial aspherical surfaces with even aspherics. Menisci 1, 2 are made of Germany. The shape of the lenses corresponds to the lens circuit shown in FIG. one.

The magnitude of the movements for focusing and thermal compensation do not exceed 5% of the focal length of the lens.

An analysis of an example implementation of the lens for the infrared region of the spectrum was carried out for a focal length ƒ '= 50 mm, an entrance pupil diameter of 55.5 mm, a relative aperture of 1: 0.9, a receiver format of 640 × 480, a pixel pitch of 0.017 mm, (image diagonal 2y '= 13.6 mm), angular field 12.4 ° × 9.3 ° (diagonal 15.5 °).

In FIG. 2 shows the frequency response graphs for various points of the field: the spatial frequency (strokes / mm) is plotted along the abscissa; along the ordinate axis is the contrast transfer coefficient (rel. units). The designation "0.0000" corresponds to the frequency response for a point on the axis; “4.08” - to the vertical edge, “5.44” - to the horizontal edge, “6.8” - to the extreme point of the diagonal of the receiver. As follows from FIG. 2, the frequency response at a Nyquist frequency of 30 lines / mm for an axial point in the image plane of at least 0.59 rel. units, for all field points with radial coordinates in the image plane equal to or less than half the size of the larger side of the sensitive area of the receiving matrix, at least 0.43 rel. units

In FIG. Figure 3 shows the distortion graph for an example of a specific design, which does not exceed 0.3% over the entire field of view.

Thus, in comparison with the closest analogue in the inventive two-lens fast lens for the infrared region of the spectrum, the relative aperture is increased by 1.1 / 0.9 = 1.2 times, the linear field in the image space is increased by 11.47 / 8.1.17 = 1.4 times, which allowed the use of a modern matrix with a format of 640 × 480 pixels with a pixel size of 17 × 17 μm, while maintaining image quality no lower than in the closest analogue.

Thus, despite the same angular fields in the examples of specific versions of the analogue and the proposed lens, these values of the angular fields in the proposed lens are provided at a 1.4 times larger focal length. This advantage leads to the fact that in the thermal imaging device in which the proposed lens is used, the range is increased. Range (detection, recognition, identification of objects) is the main target indicator for the modernization or improvement of thermal imaging devices.

Thus, the technical implementation of the proposed lens for the infrared region of the spectrum, having a combination of these distinguishing features, allows it to be paired with modern bolometric matrix photodetectors that do not require cooling to cryogenic temperatures, sensitive in the spectral range from 8 to 14 μm, with a format of 640 × 480 pixels with a step of 17 microns and get a small aperture thermal imaging device with high technical and consumer characteristics.

Thus, the presence in the lens device of new features and new relationships between the device parameters compared with the known lens devices for the infrared region of the spectrum allows to provide the specified technical result: increase the relative aperture, increase the linear image size in the image plane of the lens, which allows you to fully realize the capabilities of modern matrices with a format of 640 × 480 pixels with a pixel size of 17 × 17 microns, and providing high image quality corresponding to To this group of optoelectronic devices, and determining the novelty and inventive step of the proposed technical solutions, and the ability to manufacture the optical-mechanical plant proves its industrial applicability that a plurality of maps the high-aperture lens for infrared spectrum patentability conditions.

Literature

1. Patent US 2010/0165455. Compact two-element infrared objective lens and IR or thermal sight for weapon hawing viewing optics.

2. Patent RU 262988 C1. High-aperture infrared lens. Priority 05/25/2016, publ. 09/04/2017.

Claims (11)

1. A two-lens fast lens for the infrared region of the spectrum, containing positive menisci facing their concave surfaces to the image plane, the second surface of the first meniscus is aspherical, with both lenses made of germanium transmitting radiation in the wavelength range of 8-14 μm, different the fact that the radii of curvature of the surfaces satisfy the following relationships: R ₁ = (1.2 ÷ 1.3) ƒ; R ₂ = (1.64 ÷ 2.0) ƒ; R ₃ = (0.85 ÷ 1.1) ƒ; R ₄ = (1,1 ÷ 1,4) ƒ, where R ₁ , R ₂ are the radii of curvature of the first and second surfaces of the first meniscus, respectively; R ₃ , R ₄ are the radii of curvature of the first and second surfaces of the second meniscus, respectively;  ƒ 'is the focal length of the lens, wherein the first surface of the first meniscus and both refracting surfaces of the second meniscus are aspherical. 2. The lens according to claim 1, characterized in that it is arranged to move along the optical axis. 3. The lens according to claim 1, characterized in that it is arranged to move the second meniscus along the optical axis.

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