RU166802U1 - OPTICAL SCHEME OF HOLOGRAPHIC COLLIMATOR SIGHT - Google Patents

Abstract

1. The optical scheme of the holographic collimator sight, containing a source of optical radiation, in the course of the rays of which are sequentially placed: a reflective relief-phase hologram, a collimation lens, a beam splitting element, which provide image formation of the aiming mark in the exit pupil of the sight, and the front focus of the collimation lens is aligned with the source optical radiation, and a reflective phase-relief hologram located, for example, at an angle of 45 degrees to the optical axis of the radiation point, forms a reconstructed image in the plane of the radiation source, while the mirror and diffraction components of the radiation reflected by the hologram are within the exit pupil of the sight, the reflecting face of the beam splitter element is set at an angle, for example, 45 degrees to the axis of the radiation reflected by the hologram and combines images of the aiming mark and targets in the exit pupil of the sight along the line of sight. 2. The optical scheme of the holographic collimator sight according to claim 1, characterized in that the reflective relief-phase hologram is a physical hologram. 3. The optical scheme of the holographic collimator sight according to claim 2, characterized in that the physical reflective relief-phase hologram is a combined hologram. 4. The optical scheme of the holographic collimator sight according to claim 3, characterized in that the combined physical reflective relief-phase hologram is a hologram obtained by sequential registration on a photosensitive layer

Description

Technical field

The utility model relates to holographic collimator sights and can be used in small arms.

State of the art

Known optical collimator sight (see patent No. 4665622, NKI 33-24 USA) in which the image of the sighting mark is formed by a point source of optical radiation located in the focal plane of the collimation lens. The combination of images of the target and the aim mark is carried out in a translucent aim window so that the shooter perceives the image of the mark in the form of a luminous dot on the target. The advantage of the sight is low power consumption, while the disadvantage is the picture of the mark, which looks like a single luminous dot.

The solution known from the patent publication (see patent for utility model RU 158982, F41G 1/00, 08/07/2015) in which the optical design of the compact collimator sight contains an optical radiation source, a collimation lens, a mirror element, and a hologram optical element is selected as a prototype. (GOE), a beam splitting element, with the possibility of radiation passing from a source through a compactly located combination of a collimation lens and a mirror element, as well as through a compactly located set of holograms of the beam splitter and to the formation in the eye of the user resulting overlay image sight goals and holographic images of the impact plate. Moreover, the GOE is a computer-synthesized hologram of the framing of the central aiming point of the aiming mark, moreover, a beam directed to the central aiming point of the aiming mark is used as the hologram reference beam with the possibility of reading the hologram image from the GOE of forming the image of the central aiming point on the axis of the reading beam with the corresponding focusing this beam.

The proposed optical design of the sight coincides with the prototype in the presence and functional purpose of the following elements: optical radiation source; collimation lens; a hologram optical element representing an axial hologram of Gabor; beam splitting element.

The disadvantage of the optical circuit of the prototype is the use of a transmitting computer-synthesized hologram as a GOE. In the prototype, the GOE is a hologram of the image of the frame of the central aiming point of the aiming mark, which is formed by computer synthesis and displayed on the aperture of the LCD transparency. The resulting image of the holographic structure is optically projected onto the surface of the recording medium, exposure and photochemical processing are performed. Optical copying of holograms onto a photosensitive recording medium is a laborious process and, at the same time, requires the use of high-resolution projection equipment. In addition, in the prototype, the GOE is a transmissive hologram, the hologram structure of which requires protection from external influences, for example, by gluing with an optically transparent plate, and to eliminate reflections (glare) on the optical surfaces of the GOE, it is necessary to apply antireflection coatings.

As you know (Holography and holographic methods of quality control. Terms and definitions, GOST 24865.1-81), the hologram structure of computer-synthesized holograms is formed at individual points and has a binary low-frequency structure. Due to this structure, when reading (restoring) an image from a hologram, a parasitic light field appears near the restoring beam, which is superimposed in the case of axial holograms on the holographic image. In the prototype, the read beam and the holographic image create a single image of the mark and, therefore, spurious illumination is superimposed on the image of the mark, worsening its quality.

Another disadvantage of the optical scheme of the prototype is the type of hologram used, which is a Fourier hologram, the image of which is restored by a plane wave. In this case, the GOE must be placed along the rays behind the collimation lens, as shown in the published materials of the prototype in figure 1. In this arrangement of optical elements, the overall dimensions of the sight increase and exceed the focal length of the collimation lens.

Utility Model Disclosure

The technical result of the utility model is to simplify the design of the holographic collimator sight, to improve the image quality of the aiming mark under the condition of low power consumption.

The technical result is achieved by the fact that the proposed optical scheme of a holographic collimator sight contains a source of optical radiation, in the course of which the rays are sequentially placed: a reflective relief-phase hologram, a collimation lens, a beam splitting element, which provide image formation of the aiming mark in the exit pupil of the sight, with front focus the collimation lens is combined with the optical radiation source, and the relief-phase hologram located, for example, At an angle of 45 degrees to the optical axis of the radiation source, it forms a reconstructed image in the plane of the radiation source, while the mirror and diffraction components of the radiation reflected by the hologram are within the exit pupil of the sight, the reflecting face of the beam splitting element is set at an angle, for example, 45 degrees to the axis of the reflected hologram radiation and combines images of the aiming mark and target in the exit pupil of the sight along the line of sight.

In particular cases of the implementation of the utility model, a reflecting phase-relief hologram can be: a physical hologram; combined hologram made by physical holography methods and, in a particular case, representing a hologram of the image of point sources; a replica of the hologram obtained by contact copying. It is also possible that in a utility model the collimation lens is an off-axis reflector, the optical surface of which is combined with a relief phase hologram. In the particular case of a useful model, the radiation source is a laser diode, the supply current of which is set in the range below the threshold current at which laser generation occurs.

Utility Model Implementation

We will consider the implementation of the utility model by the example of optical circuits shown in FIG. 12.

In FIG. 1 shows the optical scheme of a holographic collimator sight and the positions are indicated: 1 - a source of optical radiation; 2 - reflecting relief phase hologram; 3 - collimation lens; 4 - beam splitting element. Radiation from source 1 by a diverging beam of rays illuminates the reflective relief-phase hologram 2 and, in diffraction orders, reconstructs from the hologram in the plane of source 1 the imaginary image of the mark (more precisely, its diffraction part). Another part of the image is formed by the mirror component of the restoring (reading) radiation. After the hologram 2, the overall image of the mark is on the same axis as the collimation lens 3 in its front focal plane. The collimation lens 3 transfers the general image of the mark to infinity, which, using the beam splitter 4, is combined with the image of the target and is sent to the eye along the line of sight.

In FIG. 2 shows the optical recording scheme of the combined reflective relief-phase hologram and the positions are indicated: 5 - laser; 6 - lens; 7 - a flat mirror; 8 is a recording medium for holography. The radiation, for example, from the He-Cd laser 5, passing through the lens 6, is focused at a point. A flat mirror 7 is mounted near this point, approximately parallel to the optical axis of the lens. The mirror oriented in this way passes part of the radiation directly, and part reflects toward the carrier 8, forming an interference pattern on it. The frequency and orientation of the interference fringes can be set by the angular and linear displacements of the mirror 7. Also, the selection of the necessary frequency and orientation of the recorded interference fringes on the carrier 8 can be made by the angular and linear displacements of the carrier 8.

One of the main problems of OKP is the formation of an image of the sighting mark with the absence of parallax over the entire field of view of the sight. In this case, the collimation lens, which ensures the formation of the aiming mark at infinity, must be of high quality and not introduce aberrations. To satisfactorily solve this problem, the lens, as a rule, should not have an angular aperture of more than ~ 1/3. The increase in aperture leads to a sharp increase in aberrations, and their correction to complicate the design of the lens. In addition, reducing the focal length of the lens in order to reduce the dimensions of the collimator sight leads to a complication of the design of the alignment mechanism (combining the line of sight of the collimator sight with the trajectory of the projectile). The focal length of the collimation lens 3 (Fig. 1), in comparison with the prototype, is increased due to the location of the lens 3 near the beam splitting element 4. This was made possible by the use of a reflective phase-relief hologram, the image from which is restored to the focus of the lens 3 using a diverging beam rays. In addition, the use of reflective relief-phase holograms made it possible to exclude the mirror element used in the prototype for directing radiation to a beam splitting element.

One of the main characteristics of collimation sights is the energy consumption of the radiation source, which depends on the losses on the optical elements that provide the formation of the image of the sighting mark. In the proposed utility model, the Gabor axial hologram is used similarly to the prototype, which allows the use of zero order, as well as (+/-) 1st diffraction orders in the image of the aiming mark. However, in this case, the problem arises of minimizing the inevitably occurring spurious illumination, which is superimposed on the image of the aiming mark. In the case under consideration, this problem is solved using a physical (analog) hologram and, in particular, a combined hologram obtained by sequentially recording interference patterns with different angular orientations on a photosensitive layer, for example, created by two point sources. The optical recording scheme of such a hologram is shown in FIG. 2. In such a recording scheme, the hologram of the sighting mark will be a combined combined hologram consisting of subholograms of images of point sources. In this case, the angular dimensions of individual elements of the image of the sign are limited by the diffraction resolution limit, which allows for high accuracy of combining the aiming mark with the target and, very importantly, the speckle structure is eliminated in the image and the parasitic background is reduced.

In the relief-phase holograms, the recorded image is presented in the form of a surface relief on the medium, contact copying (manufacturing of replicas) of which with high resolution is quite easily implemented using well-known technologies for manufacturing optical discs, phonograph records, and rainbow holograms. Such a technology for the production of holograms in the production of collimator sights seems to be the most preferable in the mass production of collimator sights due to its high performance and low cost.

The technological possibility of contact copying of relief phase holograms, in particular, makes it possible to have a combined optical element in the optical scheme of the sight, which combines the functions of a collimation lens, which is an off-axis reflector and a reflective relief phase hologram.

A special case of the implementation of the utility model reveals the possibility of using a laser diode as a radiation source, the supply current of which is set in the range below the threshold current at which laser generation occurs.

It is known that the angular divergence of the radiation of laser diodes in the laser generation mode can differ by several times in orthogonal planes (for example, by 5 times or more). Uniform illumination of the exit pupil of the sight can be ensured only if the exit pupil is completely filled with rays with minimal divergence. In this case, large energy losses occur. When the current value is below the threshold laser current, the laser diode switches to LED mode with a uniform radiation divergence. Despite the fact that the radiation spectrum expands with this mode of operation of the laser diode, this does not affect the image quality of the aiming mark, since the Gabor axial hologram, taking into account the angular dimensions of the aiming mark, has a band frequency, usually no more than 20 lines per millimeter. Such a value of the frequency of the bands with the expansion of the emission spectrum will give a blurring of the sign beyond the resolution of the eye. Experimental results showed that taking into account a significant reduction in losses on the hologram element, the energy consumption of a 5 mW laser diode (under conditions not exceeding the threshold laser generation current) is sufficient to ensure the brightness of the aiming sign under any illumination of the target.

Claims (7)

1. The optical scheme of the holographic collimator sight, containing a source of optical radiation, in the course of the rays of which are sequentially placed: a reflective relief-phase hologram, a collimation lens, a beam splitting element, which provide image formation of the aiming mark in the exit pupil of the sight, and the front focus of the collimation lens is aligned with the source optical radiation, and a reflective phase-relief hologram located, for example, at an angle of 45 degrees to the optical axis of the radiation point, forms a reconstructed image in the plane of the radiation source, while the mirror and diffraction components of the radiation reflected by the hologram are within the exit pupil of the sight, the reflecting face of the beam splitting element is set at an angle, for example, 45 degrees to the axis of the radiation reflected by the hologram and combines images of the aiming mark and targets in the exit pupil of the sight along the line of sight. 2. The optical scheme of the holographic collimator sight according to claim 1, characterized in that the reflective relief-phase hologram is a physical hologram. 3. The optical scheme of the holographic collimator sight according to claim 2, characterized in that the physical reflective relief-phase hologram is a combined hologram. 4. The optical scheme of the holographic collimator sight according to claim 3, characterized in that the combined physical reflective relief-phase hologram is a hologram obtained by sequentially recording interference patterns with different angular orientations on a photosensitive layer, for example, created by two point sources. 5. The optical scheme of the holographic collimator sight according to claim 1, characterized in that the reflective relief-phase hologram is a replica obtained by contact copying. 6. The optical scheme of the holographic collimator sight according to claim 1, characterized in that the collimation lens is an off-axis reflector, the optical surface of which is combined with a reflective phase-hologram. 7. The optical scheme of the holographic collimator sight according to claim 1, characterized in that the radiation source is a laser diode, the supply current of which is set in the range below the threshold current at which laser generation occurs.

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