RU174738U1 - INFRARED MIRROR AND LENS SYSTEM - Google Patents

Abstract

The mirror-lens system can be used in thermal imaging devices based on cooled matrix radiation detectors. The mirror-lens system consists of the first component located along the rays, containing a positive concave-convex lens, the convex surface of which with a reflective coating acts as a secondary mirror, and the main concave aspherical mirror with a central hole, the second component containing three convex-concave lenses of which the first and third are made positive, and the second negative, and the radiation receiver with a cooled diaphragm. An intermediate image is formed between the first and second components. The technical result is an increase in the angular resolution of the infrared mirror-lens system with a decrease in the tele-shortening coefficient. 1 ill., 3 tablets

Description

The utility model relates to optical instrumentation and can be used in thermal imaging devices based on cooled matrix radiation detectors.

Known mirror-lens system (see patent US 7082001 B2, publ. 07.25.2006, the circuit in Fig. 1), containing the first component that forms a valid intermediate image and consisting of a main concave aspherical mirror with a Central hole and concave-convex the lens, and its concave aspherical surface is made with a reflective coating and acts as a secondary mirror, and the second component, which transfers the intermediate image to the plane of the sensitive elements of the radiation receiver. In the second component, the first and second lenses are concave-convex, the third is biconvex, the fourth is concave-convex, and the fifth is convex-concave, and the third lens is aspheric-diffractive. In the first component, the convex-concave lens is made of germanium, three lenses of the second component are made of gallium arsenide, two of zinc selenide. The focal length of the system f 'is not more than 220 mm, the angular field of view is 2 ω = 2.64 °, and the spectral range of operation is 3.9 ... 5 μm.

The disadvantages of this system are the small value of the focal length and a large number of lenses in the second component.

A mirror lens system is also known (see RF patent 2355003 C1, IPC ⁷ G02B 17/08, publ. 05/10/2009), containing the first component consisting of a main concave aspherical mirror with a central hole, a secondary convex aspherical mirror, a compensator field aberrations made in the form of a positive convex-concave lens of zinc selenide and a second component containing a concave-convex lens of germanium, a biconvex lens of silicon, two convex-concave lenses of silicon and a convex-concave lens of germanium. An intermediate image is formed between the first and second components. The focal length of the system f '= 379.6 mm; relative aperture 1: 2.05; angular field of view 2ω = 1.8 °, spectral range of work 3 ... 5 microns. The length of the optical system from the convex surface of the secondary mirror to the plane of the sensitive elements of the radiation receiver is L = 299.6 mm. The value of the tele-shortening coefficient of the system is T _L = L / f '= 0.79.

The disadvantages of the system include a large number of lenses in the second component, as well as the large value of the tele-shortening coefficient.

Closest to the claimed system in technical essence, selected as a prototype, is a mirror-lens system (see patent CN 104035188 A, IPC ⁷ G02B 13/18, 13/14, 17/08, publ. 09.10.2014) consisting of a first component containing a first positive convex-concave lens, a main aspherical mirror with a central hole and a second flat-concave lens, with a reflective coating on a flat surface, acting as a secondary mirror, and a second component containing three lenses, of which the first is biconcave Tue ora - positive concave-convex, and the third - positive convex-concave. The first component forms an intermediate image, which is transferred by the second component to the plane of the sensitive elements of the cooled radiation receiver. The system is designed to operate in the spectral range of 3.7 ... 4.8 microns; focal length f '= 168 mm; relative aperture 1: 2; coefficient of central shielding 0.35; linear field of view 9.6 × 7.68 mm (matrix format of a photodetector 320 × 256, with a spacing of elements of 30 μm).

The length of the optical system from the first surface of the first lens to the plane of the sensitive elements of the radiation receiver is L = 150 mm, and the second component makes a significant contribution, in which the distance along the optical axis from the first surface of the first lens to the last surface of the third lens is at least 50 mm. The value of the tele-shortening coefficient of the system is T _L = L / f '= 0.9. With a focal length f '= 168 mm and a sensor element size of 30 μm, the elementary angular field of view of the system is ω _e = 30 / f' = 0.18 mrad.

The disadvantages of the prototype are the large value of the telecirculation coefficient, as well as the elementary angular field of view of the system, which does not provide sufficient angular resolution.

The problem the utility model aims to solve is to increase the angular resolution of the infrared mirror-lens system while reducing the telecirculation coefficient.

The problem is solved due to the fact that in the infrared mirror-lens system, consisting of the first component located along the rays of the first component containing the positive lens and the main concave aspherical mirror with a central hole, the second component containing the first, second and third positive convex-concave lenses while a real intermediate image is formed between the first and second components, and the radiation receiver with a cooled diaphragm, in the first component the positive lens is made a concavo-convex, with its convex surface with a reflective coating in the central zone performs the function of the secondary mirror, and the second component of the positive first lens is formed convex-concave, and the other - negative convex-concave.

The figure 1 presents the optical scheme of the infrared mirror-lens system.

The system consists of the first component I located along the rays, containing a positive concave-convex lens 1, the convex surface of which with a reflective coating in the central zone acts as a secondary mirror and the main concave aspherical mirror 2 with a central hole, the second component II, containing the first positive convex a concave lens 3, a second negative convex-concave lens 4 and a third positive convex-concave lens 5, and a radiation receiver 6 with a cooled diaphragm 7, while between th second I and II components forms a real intermediate image.

Table 1 shows the technical characteristics of the inventive infrared mirror lens system.

Table 2 shows the design parameters of an example of a specific implementation of the inventive system.

^{1), 2)} - aspherical surfaces.

Table 3 shows the ratios performed in the inventive system.

The infrared mirror-lens system works as follows: the radiation from an infinitely distant object peripherally through the ring passes through the lens 1 of the first component I, then, reflected from the concave surface of the main mirror 2, it enters the central part of the convex surface of the lens 1, is reflected from it and focuses in the plane of the actual intermediate image, after which the image formed in this plane by lenses 3,4,5 of the second component II is transferred to the plane of the sensitive elements of the radiation receiver Nia 6. The diameter of the radiation beam is determined by the diameter of the diaphragm 7 a cooled radiation receiver 6.

As follows from table 1, the focal length of the claimed system f '= 560 mm, length L = 356.3 mm, the tele-shortening coefficient of the system is T _L = L / f' = 0.635, which is 1.4 times less than in the prototype. The reduction of the telecirculation coefficient is ensured by fulfilling the ratios for the system components shown in Table 3, as well as by choosing a more compact construction of the second component II, in which the distance from the first surface of the first lens 3 to the last surface of the third lens 5 is 25 mm (see Table 2) .

In the inventive system, the elementary angular field of view for the size of the sensitive element similar to the prototype is ω _e = 30 / f '= 0.053 mrad, which is 3.4 times less than in the prototype.

Thus, the implementation of the infrared mirror-lens system in accordance with the proposed technical solution allows to increase the angular resolution, while ensuring a decrease in the tele-shortening coefficient.

Claims (1)

An infrared mirror-lens system consisting of along the rays of the first component containing a positive lens and the main concave aspherical mirror with a central hole, the second component containing the first, second and third positive convex-concave lenses, while between the first and second components is formed a valid intermediate image and a radiation receiver with a cooled diaphragm, characterized in that in the first component the positive lens is concave-convex, and its convex surface with a reflective coating in the central zone acts as a secondary mirror, and in the second component, the first lens is made convex-concave positive, and the second is convex-concave negative.

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