RU95140U1 - HOLOGRAPHY COLLIMATOR SIGHT AND RECORDING COMPENSATION HOLOGRAM OPTICAL ELEMENT RECORDER - Google Patents

Abstract

 1. A holographic collimator sight containing a semiconductor laser diode sequentially mounted on the optical axis, emitting at a red radiation wavelength, a rotary flat mirror, an off-axis spherical mirror, a hologram reflective diffraction grating, a hologram optical element forming an imaginary image of the aiming mark in the aiming space, characterized the fact that it has an additional semiconductor laser light diode emitting at a green radiation wavelength, about The laser optical radiation uniting these semiconductor sources is a mirror optical system located between the laser light sources and the hologram optical element and the compensation hologram optical element located between the integrating mirror optical system and the hologram optical element. ! 2. A recording device for a compensation hologram optical element for a holographic collimator sight, comprising a laser light source, an optical system for forming the reference and target beams, a diffuser, an aiming sign transparency and a photographic plate, sequentially installed in the object beam, characterized in that between the photographic plate and the aiming sign transparency a second lens is mounted on the object beam, and the transparency is located along the rays near the front focal plane of the second volume In addition, a mechanism for displacing the transparency along the optical axis of the object beam and a mechanism for displacing the diffuser relative to the transparency of the aiming mark are installed.

Description

Technical field

The technical solution relates to holographic collimator sights, forming an imaginary image of the sighting mark, and to devices for recording hologram optical elements (GOE) of sights.

State of the art

Known holographic collimator sights for use on hand small arms, forming an imaginary image of an aiming mark in the aiming space. These sights include a laser light source, a lens that collimates the radiation from the source, a hologram optical element that forms an imaginary image of the sighting mark in the aiming space, achromatic optical system in the form of a diffraction grating (US No. 6,490,060 B1 of Dec. 3, 2002, [1]) or a combination of prisms with a diffraction grating (US No. 5,483,362 of Jan. 9, 1996, [2]), which compensates for the angular displacement of the observed sighting image due to the temperature deviation of the source radiation wavelength. The disadvantages of these sights are:

1. significant dimensions and mass of optical recovery schemes from the hologram optical element of the imaginary image of the sighting mark,

2. the presence of a single image of the sighting mark in the absence of the possibility of its displacement along the line of sight. When aiming at objects at different distances, significantly different from the distance at which the image of the aiming mark is located, the accuracy of aiming due to parallax or discrepancies between the object and the aiming mark decreases.

As a prototype adopted the closest in technical essence to the claimed is a holographic collimator sight (US No. 2006/0164704 A1 of Jul. 27, 2006 [3]). In this patent, the optical circuit of the sight includes a laser diode sequentially mounted along the optical axis, a rotary flat mirror, an off-axis spherical mirror, a hologram reflective diffraction grating, and a hologram optical element.

This sight also has the following disadvantages:

1. significant dimensions and mass of the optical recovery scheme from the hologram optical element of the imaginary image of the sighting mark,

2. the presence of only a single image of the sighting mark, restored from the hologram optical element, and the impossibility of its displacement along the line of sight,

3. The manufacture of a collimating mirror in the form of a single optical part made of glass with two spherical surfaces does not allow minimizing spherical aberration to ensure the required divergence of the laser radiation when illuminating the GOE. This leads to additional hologram aberrations and an increase in the parallax of the reticle when it is restored.

In addition, in the schemes of hologram recording devices for forming an imaginary image of two-dimensional objects, which include a sighting sign transparency, in the general case (R. Koliere, K. Burkhart, L. Lin, Optical holography, Mir ed., M., 1973, p. 224, [4]), a diffuser located in the object beam along the rays in front of the banner is used. This determines the speckle structure of the observed imaginary image, because of which its contours are blurred and become not clear.

Also known (R. Koliere, K. Burkhart, L. Lin, Optical holography, ed. Mir, M., 1973, p. 243, [4]) recording schemes that are used when restoring an image from a hologram optical element without taking into account large-scale distortions, including the parameter µ, defined as the ratio of the wavelength of light λ ₂ at which the image of the aiming mark in the sight is restored to the wavelength of light λ ₁ at which the hologram optical element is recorded. In aiming systems, laser diodes with the recovery wavelength of the imaginary image of the aiming sign λ = 0.620-0.660 μm are mainly used, while the He-Cd laser with the wavelength λ = 0.4416 μm is used to record the phase-holograms on the photoresist. This leads not only to large-scale distortions of the reconstructed image, but also to aberration distortions introduced by the hologram optical element. To solve the above problems to create hologram optical elements, modified recording and restoration schemes are used.

The essence of the utility model.

The first task of the utility model is to create a holographic collimator sight with the elimination of the disadvantages of analogues.

The technical result of the utility model is the formation in the aiming space of an image of two sighting signs containing components of red and green colors, as well as the construction of a lensless optical circuit of a holographic collimator sight, which minimizes the number of components included in it;

The second task of the utility model is to create a recording device for a compensation hologram optical element for forming an imaginary image of an aim mark in a holographic collimator sight according to claim 1.

The technical result of the utility model is the ability to restore several images of the aiming mark on a hologram optical element, forming two images of sighting signs in different colors in the aiming space, as well as obtaining a hologram optical element, which, when working in the sight, provides increased clarity of the observed contours of the sighting image.

In the claimed holographic collimator sight, the technical result is achieved due to the fact that in the sight containing a semiconductor laser diode (with a wavelength λ _{1 of} red color) sequentially mounted on the optical axis and a hologram optical element that forms an imaginary image of the sighting mark in the aiming space are additionally installed :

1. a second semiconductor laser diode with a wavelength of radiation λ ₂ green,

2. combining the radiation of the sources of the mirror optical system located between the light sources and the hologram optical element,

3. compensation hologram optical element located between the radiation source combining radiation of the mirror optical system and the hologram optical element.

In a recording device for a compensation hologram optical element (KGOE) for imaging two reticle in a holographic collimator sight, the technical result is achieved due to the fact that in the device containing a laser light source (He-Cd laser with a radiation wavelength λ ₁ ), the optical system the formation of the reference and subject beams, sequentially installed in the subject beam, a diffuser, an aiming sign transparency and a photographic plate, and both the reference and subject beams are diverging Isya. Moreover, the transparency is located along the rays behind the front focal plane of the lens (installed in the subject beam), and a mechanism for displacing the transparency along the optical axis of the subject channel has been introduced. At the same time, the compensation hologram optical element of the same color of the image of the aiming mark is recorded in several successive exposures, in each of which the diffuser is in a position arbitrarily shifted relative to the positions at other exposures.

Description of utility model and figures

Figure 1 presents a lensless optical diagram of a holographic collimator sight, which forms in the aiming space an image of two sighting marks containing components of red and green colors.

Figure 2 presents the optical recording scheme of the compensation hologram optical element.

As radiation sources in the holographic collimator sight (FIG. 1), several semiconductor laser diodes or semiconductor LEDs 1 with different radiation wavelengths are used. In this example, we use two semiconductor laser diodes 1a and 1b, emitting respectively in the green and red regions of the spectrum (at the radiation wavelengths λ _2a , λ _2b, respectively). The simultaneous use of these light sources is ensured by a mirror optical system combining the radiation of the sources, located between the light sources and the compensation hologram optical element (KGOE) 4, in this case a conventional mirror 2, a dielectric mirror 3, reflecting light at the wavelength of the source 1b and with transmission, are used, close to 1 at a different wavelength. When light sources are in the focal plane of the compensation hologram optical element 5, parallel radiation beams are formed at its output at all used wavelengths. The displacement of any of the sources 1 along the optical axis relative to the focal plane of the compensation hologram optical element using the same mechanisms of movement 9 for all sources leads to the formation of QHE to varying degrees for different wavelengths of converging or diverging homocentric beams. Then the light falls on the hologram optical element 5, diffracts on its periodic system, the arrow 6 enters the eye and then forms a visible imaginary image of the sighting mark in the aiming space.

In principle, a holographic collimator sight can be used only with a fixed position of the light sources 1 relative to the hologram optical element 5.

Also in the considered scheme, a change in the angular position of the aiming mark when changing such a parameter as temperature is minimal and practically does not affect the operation of the sight at short distances. For example, for axial rays forming an imaginary image of the center of the sighting mark, there is a complete compensation for the change in the wavelength of the light of the source. It doesn’t matter if this change is determined using a light source with a relatively wide spectral band of radiation, more specifically, an LED light source, whether the wavelength of the source light is due to a change in temperature, or, moreover, the use of several light sources with different wavelengths their radiation.

The compensation hologram optical element 4 is registered in such a way that when light is incident on it from a laser radiation source, the spherical wavefront is converted to a flat one at two radiation wavelengths of the semiconductor laser LEDs (in the green and red spectral regions).

The hologram optical element 5 is registered in such a way that when reconstructing the image of the sighting mark, an imaginary image of the sighting mark of two colors is formed at each wavelength of the light used. In the case considered for an example with two registered components in a hologram, these components are formed with centers on the aiming line in each of the groups Va, Vb at two points spaced in space along the aiming line and located at distances Lij, where the first index corresponds to the wavelength used, the second - the number of image components in the color group.

The conversion in a holographic collimator sight by a compensating hologram optical element 4 of a spherical wave front to a plane is provided by the recording device of the compensation hologram optical element (FIG. 2). The hologram is recorded at a wavelength λ _{1 of} a coherent light source, generally different from the wavelength λ _{2 of the} light used in a holographic collimator sight. The source light is appropriately divided into two beams designed to form the reference and object beams on the plate 7a with a layer sensitive to light at a wavelength of λ ₁ (the input part of the recording device in FIG. 2 is not shown). The compensation hologram optical element is recorded in several exposures corresponding to the number of wavelength components at which the QHE will operate. In the case considered as an example, a compensation hologram optical element converts a spherical wavefront into a flat one at two wavelengths (the red and green spectral regions). In each exposure, one and the same parallel reference beam incident on the plate 7a at an angle α ₁ and homocentric object beams diverging to various degrees whose axes are normal to the plate at an angle α _{2 are used} . The angles α ₁ and α ₂ in step KGOE and recording angles β ₁ and β ₂ in step recovery imaginary aiming mark image by using as a part of the sight KGOE known equations associated grating.

The object in the object beam is the imaginary image of the aiming sign transparency 12 formed by the second lens 13, which is an opaque plate with a transparency zone corresponding to the configuration of the aiming sign and is set at the point Ptr along the rays behind the front focus F _{13 of the} lens. A first lens 10 and a diffuser 11 are installed in front of the transparency along the rays, together with the condition that the first lens 10 forms an image of a light source in the center of the lens 13 that ensures uniform use of light from all points of the transparency when the aperture of the lens is uniformly filled.

The offset Δmp of the transparency of the aiming mark 12 relative to the focal plane of the first lens 13 using the mechanism 14 provides a diverging subject beam with a center of divergence at point P at a distance Lp from the center of the lens along the optical axis of the lens.

The result of the use of the technical solutions proposed in the application is the creation of a holographic collimator sight, which has significant functional advantages compared to existing analogues and the considered prototype. These advantages are expressed in the formation in the aiming space of the image of two sighting signs containing components of red and green colors, as well as in minimizing the number of optical elements included in the optical scheme of the holographic collimator sight.

Bibliography

1. Anthony M. Tai, Eric J. Sieczka. Lightweight holographic sight, Patent US No. 6,490,060 B1 of Dec. 3,2002.

2. Anthony M. Tai, Juris Upatnieks, Eric J. Sieczka. Compact holographic sight, Patent US No. 5,483,362 of Jan. 9.1996.

3. Eric J. Sieczka, Anthony M. Tai, Robert H. Fish. Low profile holographic sight and method of manufacturing same, Patent US No. 2006/0164704 A1 of Jul. 27, 2006. - prototype

4. R. Colier and others, Optical holography, ed. "The World", M., 1973.

Claims (2)

1. A holographic collimator sight containing a semiconductor laser diode sequentially mounted on the optical axis, emitting at a red radiation wavelength, a rotary flat mirror, an off-axis spherical mirror, a hologram reflective diffraction grating, a hologram optical element forming an imaginary image of the aiming mark in the aiming space, characterized the fact that it has an additional semiconductor laser light diode emitting at a green radiation wavelength, about The laser optical radiation uniting these semiconductor sources is a mirror optical system located between the laser light sources and the hologram optical element and the compensation hologram optical element located between the integrating mirror optical system and the hologram optical element. 2. A recording device for a compensation hologram optical element for a holographic collimator sight, comprising a laser light source, an optical system for forming the reference and target beams, a diffuser, an aiming sign transparency and a photographic plate, sequentially installed in the object beam, characterized in that between the photographic plate and the aiming sign transparency a second lens is mounted on the object beam, and the transparency is located along the rays near the front focal plane of the second volume In addition, a mechanism for displacing the transparency along the optical axis of the object beam and a mechanism for displacing the diffuser relative to the transparency of the aiming mark are installed.