RU2736285C1 - Surveillance device - sight with built-in laser range finder - Google Patents

Abstract

FIELD: optics.

SUBSTANCE: device can be used in optoelectronic devices of fire control systems of armored vehicles. Surveillance apparatus comprises a head portion and two vertically arranged channels: visual optical variable magnification and multiple thermal imaging channels. Visual optical channel inversion system comprises three components. First component consists of negative convex-concave, negative concave-convex and biconvex lenses, the second one contains positive concave-convex lens, the third one – gluing from negative convex-concave lens facing with convexity to object, and biconvex lens. Field corrector is a positive concave-convex lens. First, second and third components of the inversion system are movable along the optical axis in two extreme positions.

EFFECT: providing perception of objects of the same value as in observation with the naked eye, by increasing the optical magnification of a single visual channel and increasing the visual field of the multiple optical visual channel.

1 cl, 3 tbl, 2 dwg

Description

The proposed invention relates to the field of optoelectronic technology and can be used in the fire control system of armored vehicles.

Known observation device-sight with a built-in pulsed laser rangefinder (patent RU 2526230 C1, priority 13.02.2013), containing a single day channel and multiple day / night channel with switching visual observation to an image converter, as well as a laser rangefinder channel, in which the receiving branch is combined with the daytime single channel, and the transmitting branch is made separate.

The daytime single channel includes protective glasses, a prism-cube, an objective consisting of three components, a collective consisting of a biconvex lens, an inclined plane-parallel dichroic plate, a two-component wrapping system, a rectangular prism, a plane-parallel plate, and an eyepiece consisting of four components. the first of which is a negative plano-concave lens facing the object with its concavity, on the flat side of which aiming marks are applied, the second is a glued lens made of a biconcave and biconvex lenses, the third component is a glued lens of a biconvex and negative convex lens, the fourth component is a biconvex lens.

The optical path of the receiving device includes a lens and a collective of a single channel, a dichroic plate installed between the collective and a wrapping system of a single channel, which transmits the visible spectral range and reflects a wavelength of 1.54 μm, a matching optical system, consisting of three components, and a photodetector of the range finder.

The disadvantages of this device are the complexity of the implementation of separate daytime single and multiple channels with switching in a multiple channel to an image intensifier for night operation, and the need for active backlighting in low light conditions on the ground. The use of a multiple visual channel with its switching to an electron-optical converter makes it difficult to use the thermal imaging channel in the second channel.

The closest in technical essence is a combined observation device-sight with a built-in pulse laser rangefinder (patent RU 2698545 C2, priority 03.10.2017), containing an optical visual channel of variable magnification, a multiple thermal imaging channel containing a thermal imaging lens, a thermal imaging photodetector, a microdisplay and an eyepiece , as well as the channel of the laser rangefinder, in which the receiving branch is combined with the daytime visual channel, and the transmitting branch is made separate.

The optical visual channel contains protective glasses, a prism-cube, a lens, a collective, a two-component wrapping system, the first component of which contains a negative convex-concave lens, a negative concave-convex lens and a biconvex positive lens, and the second component contains a positive biconvex lens and a bonded lens, Consisting of a negative convex-concave lens facing the object and a biconvex lens along the beam path, the channel also contains three rectangular prisms, a plane-parallel plate, a field corrector made in the form of a negative concave-convex lens, a movable and fixed grid, an eyepiece and a matching an optical system with a rangefinder photodetector.

This version of the observation device-sight with a built-in laser rangefinder allows you to combine two optical visual channels - single and multiple channels into one with switching in it to single (with 1x magnification and 49 ° field of view) or multiple magnification (with 8x magnification and field vision 6 °) by moving the two components of the turning system, and use a thermal imaging path in the second channel, providing night observation in insufficient ambient light without using active illumination, while maintaining the possibility of placing the rangefinder's photodetector in the optical system of the combined daytime channel.

The disadvantages of this device are a small magnification of the visual single channel, equal to 1 times, since the practice of using low magnification optical devices shows that when examining the terrain through a system with a magnification of 1 times, all objects seem to the observer somewhat reduced (Optics in military affairs. Volume 2. Under ed. by S.I.Vavilov and M.V.Savostyanova, - 3rd ed., revised and supplemented - Moscow, Leningrad: Publishing house of the Academy of Sciences of the USSR, 1948, p. 59.), as well as small angular the field of view of the visual multiple channel is 6 °, which limits the possibilities of combat work with a magnification of 8 times.

The objective of the present invention is to increase the magnification value of a single optical visual channel from 1 times to 1.2 times while maintaining the existing field of view of 49 ° and image quality, as well as to increase the field of view of a multiple optical visual channel from 6 ° to 7.5 ° s maintaining the existing 8x magnification and image quality.

The technical result, due to the task, is achieved by the fact that in the observation device-sight with a built-in laser rangefinder, containing a head part consisting of protective glasses, a prism-cube and a head mirror, and two vertically located channels: visual optical variable magnification and multiple thermal imaging containing a thermal imaging lens, a thermal imaging photodetector, a microdisplay and an eyepiece, a visual optical channel contains a lens, a collective, a wrapping system, in which the first component consists of three lenses - a negative convex-concave lens, a negative concave-convex lens and a biconvex positive lens, three rectangular prisms, a plane-parallel plate, a field corrector, a movable and fixed grid, an eyepiece and a matching optical system with a rangefinder photodetector, unlike the known one, the turning system contains three components, and the second component of the turning system is i with a positive concave-convex lens, the third component is glued from a negative convex-concave lens facing the convexity of the object and a biconvex lens, and the field corrector is a positive concave-convex lens, with the first, second and third components of the turning system made movable along the optical axis in two extreme positions with the values of axial displacements obeying the following relations:

;

;

;

;

where Δd _1k-ob is the value of the axial displacement of the first component of the turning system;

Δd _2k-ob is the value of the axial displacement of the second component of the turning system;

Δd _3k-ob is the value of the axial displacement of the third component of the turning system.

A diagram of an observation device-sight with a built-in laser rangefinder in the position of the components of the reversing system for different magnifications is shown in Figures 1 and 2.

An observation device-sight with a built-in laser rangefinder contains protective glasses 1 and 2, a common input head prism-cube 3, an objective 4, 5, 6 and 7, a second prism-cube 8, a rangefinder photodetector 9, a matching lens 10, collective 11, the first component of the wrapping system 12, 13 and 14, the second component of the wrapping system 15, the third component of the wrapping system 16 and 17, rectangular prisms 18, 19 and 20, plane-parallel plate 21, field corrector 22, movable and fixed reticle 23, eyepiece 24, 25 , 26, 27 and 28 and exit pupil 29.

The design parameters of a variant of an observation device-sight with a built-in laser rangefinder are shown in Table 1.

Figure 1 shows a diagram of a sighting device with a built-in laser rangefinder in the position of the components of the reversing system at a single magnification. A diagram of an observation device-sight with a built-in laser rangefinder with the position of the components of the reversing system at multiple magnification is shown in figure 2.

The technical parameters of the observation device-sight with a built-in laser rangefinder are given in Table 2.

The principle of operation of the observation device-sight with a built-in laser rangefinder is as follows.

The radiation from the object passes through the protective glasses 1, 2 and the prism-cube 3. Objectives 4, 5, 6 and 7 of the optical channel build an inverted image of the object and at the same time is the lens of the optical path of the receiving device of the laser rangefinder, in which the laser radiation reflected from the object with a length waves of 1.54 microns are reflected from the dichroic surface of the second along the beam of the prism entering the prism-cube 8, and is focused by a positive lens 10 on the photodetector of the range finder 9. The collective lens 11 reduces the overall dimensions of the subsequent optical components. The first component of the turning system 12, 13 and 14, together with the second component 15 and the third component 16 and 17, rotate the image and transfer it to the focal plane of the eyepiece 24, 25, 26, 27 and 28, in which the movable and fixed reticle 23 is installed with sighting marks and scales. The field corrector, made in the form of a positive concave-convex lens 22, corrects the field aberrations of the optical channel. Rectangular prisms 18, 19 and 20 form the periscope of the optical channel, and the light filter 21 protects against residual laser radiation. The first 12, 13, 14, second 15 and third 16, 17 components of the wrapping system are made movable along the optical axis in two extreme positions shown in FIG. 1 and FIG. 2, due to which, respectively, a single and multiple magnification in the optical channel is ensured, while the following relations are satisfied:

;

;

;

;

where Δd _1k-ob is the value of the axial displacement of the first component of the turning system;

Δd _2k-aboutb - the value of the axial displacement of the second component of the turning system;

Δd _3k-оb is the value of the axial displacement of the third component of the turning system.

The variable air gaps between components are shown in Table 3.

The values of the axial displacement of the components of the turning system in this embodiment are respectively equal to: Δd _1k-ob = 76.2 mm, Δd _2k-aboutb = 65.4 mm, Δd _3k-aboutb = 82.1 mm and satisfy the above ratios.

Such an observation device-sight with a built-in laser range finder ensures the perception of objects of the same size as when observing with the naked eye, by increasing the value of the optical magnification of a single visual channel to 1.2 krat.

The value was selected based on the following recommendations. The recommended magnification values for marine periscopes are in the range (1.2 ÷ 1.5) times (KE Solodilov. Military optical-mechanical devices. State publishing house of the defense industry, Moscow, 1940, pp. 53-54). For land applications in fire control systems of armored vehicles, it is advisable to use a lower magnification value of 1.2 times, while maintaining the existing field of view of 49 ° and image quality, as well as providing an increase in the field of view of the multiple visual channel from 6 ° to 7.5 ° while maintaining the optical magnification of the visual channel 8 times and image quality.

It is advisable to evaluate the quality of the optical image taking into account the capabilities of the eye (NP Zakaznov, SI Kiryushin, VN Kuzichev. Theory of optical systems: A textbook for students of instrument-making specialties of universities, - 3rd ed., Revised and add. - M .: Mashinostroenie, 1992. - 448 p .: p. 344.) and being guided by the values of the residual angular spherical aberration 1 ... 2 'recommended for binoculars and geodetic instruments, and taking into account chromatism - 2 ... 3'.

The calculated assessment of the image quality was carried out according to the values of transverse aberrations in the focal plane of a paraxial lens with a focal length of 100 mm installed in the exit pupil of the channel. With this method, the ratio of lateral and angular aberrations is: 10 μm = 20.6``.

The residual angular spherical aberration by the standard deviation at the center of the channel's field of view 1.2 times will be:

23.743 × 20.6 / 10 = 48.9 '' or 0.815 '.

The residual angular spherical aberration by the standard deviation in the center of the channel's field of view 8 times, taking into account chromatism, will be:

82.168 x 20.6 / 10 = 169.2 '' or 2.821 '.

As can be seen from the calculations, the image quality in the central part of the field of view at each magnification meets the high tolerance criteria for residual aberrations.

The observation device-sight with a built-in laser rangefinder provides an increase in the magnification value of a single optical visual channel from 1 times to 1.2 times while maintaining the existing field of view of 49 ° and image quality, as well as an increase in the field of view of a multiple optical visual channel from 6 ° to a value 7.5 ° while maintaining the existing 8x magnification and image quality.

Claims (6)

Observation device - a sight with a built-in laser rangefinder, containing a head part consisting of protective glasses, a prism-cube and a head mirror, and two vertically located channels: a visual optical variable magnification and a multiple thermal imaging one, containing a thermal imaging lens, a thermal imaging photodetector, a microdisplay and an eyepiece , a visual optical channel containing a lens, a collective, a turning system in which the first component consists of three lenses - a negative convex-concave lens, a negative concave-convex lens and a biconvex positive lens, three rectangular prisms, a plane-parallel plate, a field corrector, movable and a fixed reticle, an eyepiece and a matching optical system with a rangefinder photodetector, characterized in that the reversing system contains three components, the second component of the reversing system being a positive concave-convex lens, the third component being glued from a negative a convex-concave lens, convex to the object, and a biconvex lens, and the field corrector is a positive concave-convex lens, while the first, second and third components of the turning system are made movable along the optical axis in two extreme positions with the values of axial displacements, obeying the following relationships:

;

; where Δd _1k-ob is the value of the axial displacement of the first component of the turning system; Δd _2k-aboutb - the value of the axial displacement of the second component of the turning system; Δd _3k-оb is the value of the axial displacement of the third component of the turning system.

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