RU2215970C1 - Protective device for input optics of optical and optical- electron instruments - Google Patents

Abstract

FIELD: optical instrumentation. SUBSTANCE: reflective coat is deposited on face surface of reflecting element for reflection of incident external radiation in direction of source of external radiation and for provision of serviceability of optical and optical-electron instruments through the remaining transparent portion of input optics. EFFECT: increased efficiency of optical and optical-electron instruments used under combat conditions thanks to active-passive protection of their input optics. 15 cl, 3 dwg

Description

 The invention relates to the field of optical instrumentation, laser technology and military equipment, and in particular to a device for the input optics of optical systems, in particular, to structural elements for protecting the input optics of optical and optoelectronic devices, mainly military-military equipment, for example, structural elements for protecting the input optics of optical and optical electronic systems used to aim at the target (sights), for example for small arms: carbines, rifles, including sniper rifles, machine guns, etc .; tank fire control systems; artillery mounts, for example, in optical systems for aiming self-propelled shells in guided weapon systems with tele-orientation in the laser beam; rocket launchers, etc .; as well as the input optics of optical and optoelectronic devices, for example, observation, reconnaissance, range measuring devices, etc., and, as a result, protect the optical and optoelectronic devices themselves from radiation exposure, including laser radiation visible , IR, UV and other ranges of the electromagnetic spectrum.

 Recently, in connection with military conflicts in Iraq, Yugoslavia and Afghanistan, the problem of protecting the input optics of weapons and military equipment has become especially acute. This is due to the fact that at present, third-generation night vision devices (NVD) are widely used in reconnaissance and surveillance, including optical locators, laser rangefinders, infrared NVD, etc., which make it possible to observe weapons and military equipment when exposed to their radiation in the visible , UV and IR areas of the electromagnetic spectrum, followed by, if necessary, exposure to their input optics, for example, laser radiation, causing its failure as a result of matting, destruction of optics, etc. Existing technical solutions for protecting the input optics of weapons and military equipment are mainly related to passive defense methods, which does not allow effective combat with enemy surveillance and reconnaissance equipment, thereby reducing the effectiveness of weapons and military equipment using optics.

 Known is the armored enclosure of the input optics of a thermal imaging sight, containing an armored cap of the sight with a protective glass, an armored cover with a hole corresponding to the sight field of view of the sight, taking into account pumping angles in the vertical plane, an additional armored cover installed in front of the armored cover with slotted openings, a quick-opening opening drive and cover thickness providing compensation for a decrease in its strength due to slotted holes, and a wiper, while around the perimeter of the hole in the armor cover and outside, along the perimeter of the additional armor cap, collars are installed, the width and height of which are equal to the thickness of the corresponding caps, and the holes are placed with the possibility of providing optical transparency of the armor caps in front of the input optics of the sight (RF patent 2125222, F 41 G 1/00, F 41 H 5/26 , 1999).

 During the combat use of objects inside the reserved volume, air is supplied from the hydropneumatic cleaning system of the object under a pressure slightly exceeding the maximum value of atmospheric pressure. Protection of the entrance optics of the sight is achieved by the fact that with the armor cover 7 closed, the total area of the slotted holes is hundreds of times smaller than the area of the protective glass. When the armor cover is open 7, the area of the hole not covered by the main armor cover is several tens of times smaller than the area of the protective glass. To operate using a laser rangefinder and rocket control equipment, an armored cover with a drive opens during range measurement or during the flight of a guided missile. In other cases, it is in the closed position. Installing an armor cap with a gap relative to the input optics will not lead to its defeat when bullets and fragments hit the cap resulting in a pulsed shock. The clearance will ensure the normal operation of the wiper.

 The known technical solution allows to protect the input optics from moving bullets and fragments, and also reduces the sector of damage by light radiation, laser radiation, prevents the penetration of incendiary mixtures to the input optics of the sight. To increase the protection of the input optics of the device when the enemy uses a nuclear weapon from the signal coming from the collective defense system, the lid is closed with a drive for the duration of the shock wave. And even if the input optics of the sight are damaged in the locations of the slit openings, this does not reduce the effectiveness of the fire, since the slit openings are located behind the projection zone of the sighting marks at all elevation and decrease angles.

 However, the protection of the elements of the input optics of the sight according to the well-known technical solution is cumbersome, expensive and, most importantly, passive, and there is no active struggle with reconnaissance and surveillance equipment (optical locators, laser rangefinders, third-generation infrared NVDs, etc.) and moreover, in the case of operation using a laser rangefinder and rocket control equipment, the armored cover with the drive opens during the range measurement or during the flight of the guided missile, which makes the input elements protected Oh optics scope during this period of time is ineffective.

 The closest technical solution (prototype) is an optical sight containing a tubular body and a light source located at its rear end and at its front end an input optics that provides aiming at the target, in the form of a reflective lens with a protective device in the form of reflective in the region of wavelengths radiation of the coating light source on the back surface of the reflective lens to prevent visibility of the radiation of the light source through the lens, absorbing coatings on the front surface of the lens and the protective coating, on Eseniya absorbing coating on the lens, wherein the light source is arranged to reflect its light from the rear surface of the lens when forming an image of the aiming mark on reflective lens (patent WO 97/00419, F 41 G 1/34, 1997).

 However, the protection of the elements of the input optics of the sight according to the known technical solution is passive through the use of a coating system (protective and absorbing on the front surface of the lens and reflecting on its back surface, designed to mask the front optics of the optical sight from reconnaissance and surveillance means of the enemy, while actively fighting reconnaissance and surveillance tools (optical locators, laser rangefinders, infrared night vision devices, etc.) are not conducted, which reduces the effectiveness of such protection lementov input optical sight.

 It is known that the weakness of third-generation NVDs is that visibility, for example, in infrared NVDs deteriorates when they fall into the field of view of bright light sources. If light from fires, lighting missiles, large bonfires, etc., enters the receiver, for example, infrared night vision devices, then a phenomenon resembling the temporary blinding of a car driver with the headlights of an oncoming car is observed. A bright spot appears in the device, which prevents the observation of objects with a lower brightness. Exposure to the NVD receiver (optical locator, laser range finder, etc.) of sufficiently powerful radiation can generally lead to its failure. And under certain conditions, third-generation NVD itself (an optical locator, a laser range finder, etc.) can be such a source of powerful radiation, for example, laser, which strikes its own receiving equipment, often using laser radiation with parameters sufficient to destroy the input optics.

 Therefore, the new achieved technical result of the present invention is to increase the efficiency of optical and optoelectronic devices in combat conditions by providing active-passive protection of their input optics.

 A new technical result is achieved by the fact that in the protective device of the input optics of optical and optoelectronic devices, containing the input reflective element with a reflective coating, in contrast to the prototype, the reflective coating is applied to the front surface of the element with the possibility of reflecting incident on the reflective coating when the input reflecting element is located. external locating radiation in the direction of the source of external locating radiation and ensuring the operability of optical and optoelectronic devices moat through the rest of the transparent part of the input optics.

 The input reflective element can be made in the form of an input optical reflective element with the ability to ensure the operability of optical and optoelectronic devices through the rest of the transparent part of the reflective optical element.

 The input optical reflective element may be made of an optical material activated by a phosphor, the spectral absorption band of which corresponds to the spectrum of the locating radiation.

 At least one additional optical element can be introduced into the protective device, each of which is made of optical material activated by a corresponding phosphor, all installed in series with an air gap relative to each other, while the luminescence spectrum of the phosphor of the previous optical element corresponds to the spectral band absorption of the phosphor of the subsequent optical element.

 An absorbing coating may be introduced into the protective device, which is arranged to absorb the additional optical elements of the luminescent radiation emerging from the ends, and / or the input optical reflecting element, and all additional optical elements, if any, can be made with the ends open.

 The reflective coating can be multilayer with the possibility of reflection of at least one corresponding layer of the reflective coating of the incident external radiation of various electromagnetic wavelength ranges incident on it.

 A protective coating may be applied to the front surface and / or the reflective coating of the reflective optical element.

 The input optical reflective element can be made in the form of an input reflective lens, while the reflective coating is applied to the front surface of the lens along its periphery with the possibility of ensuring the operability of optical and optoelectronic devices through the transparent central part of the lens.

 The input reflective element may be made in the form of a protective glass.

 A reflective coating can be applied to a transparent working and / or opaque non-working part of the front surface of the element.

 A wiper can be inserted into the protective device, which is installed with the possibility of cleaning the front surface of the reflective element.

 The input reflective lens can be made in the form of an input reflective lens of an optical sight, which provides aiming at the target, while the reflective coating is applied to the front surface of the lens along its periphery with the possibility of aiming through the transparent central part of the lens.

 An additional absorbent coating may be applied to the front transparent center portion of the reflective lens.

 A protective coating may be applied to the additional absorbent coating and / or reflective coating of the reflective lens.

 In addition, a light source can be introduced into the optical sight, which is capable of forming an aiming mark image on the reflective lens when the back surface of the reflecting lens is highlighted by it; a coating reflecting in the wavelength region of the light source is applied to the back surface of the reflecting lens to reflect light source radiation from the back the surface of the lens and prevent the visibility of radiation from the light source through the lens.

 In FIG. 1, 2 are schematic diagrams of the protective device of the input optics of optical and optoelectronic devices.

 The protective device of the input optics 1 of optical and optoelectronic devices 2 contains an input reflective element, for example, in the form of a protective glass 3 with a reflective coating 4 deposited on the front surface 5, for example, on an opaque non-working part of the front surface of the element 3, with the possibility of locating the input reflecting element 3 of the reflection incident on the reflecting coating 4 of the external location radiation 6 in the direction of the receiver 7 of the source of external location radiation 6 and ensure the operability of optical and optoelectronic devices 2 through the rest of the transparent part 8 of the input optics 1 (figure 1).

 The protective device of the input optics 1 of optical and optoelectronic devices 2 can be made in the form of an input optical reflecting element 9 made of an optical material activated by a phosphor 10, the spectral absorption band of which corresponds to the spectrum of the locating radiation 6, and may contain at least one more additional optical element 11 (figure 2 shows 2 such additional optical element 11), each of the optical elements 9, 11 is installed in series with an air gap of 12 rel relative to each other, in this case, the luminescence spectrum of the phosphor 10 of the previous optical element 9, 11 along the radiation 6, corresponds to the spectral absorption band of the phosphor 10 of the subsequent additional optical element 11, and the reflective coating can be made in the form of a multilayer reflective coating 13 with the possibility of reflection at least one corresponding layer of reflective coating 13 of the incident external radiation incident on it 6 different electromagnetic wavelength ranges, while on the front a surface 5 and / or a reflective coating 13, for example on the front surface 5 and the reflective coating 13 of the reflective optical element 9, a protective coating can be applied 14. It can also be installed with the possibility of cleaning the front surface 5 of the reflective element 9 with a wiper 15 (on figure 2).

 The protective device can be made in the form of input optics 1, for example, an input reflective lens 16 of the optical sight 17, which provides aiming at the target and is located at the front end of the optical sight, while the reflective coating 4, 13 is applied to the front surface 5 of the lens 16 along its periphery 18 with the possibility of aiming through the transparent Central part 19, and on the front transparent Central part 19 of the reflective lens 16 can be applied an additional absorbent coating 20, while on the additional coating 20 is absorbed and / or reflecting layer 4, 13 a reflective lens 16, the protective coating 14 (FIG. 3) may be applied. If there is a light source 21 in the optical sight 17 that is capable of forming an aiming mark image when the back surface 22 of the reflecting lens 16 is highlighted by it, a coating 23 reflecting in the wavelength region of the light source 21 can be applied to reflect radiation the light source 21 from the back surface 22 of the lens 16 and to prevent the radiation of the light source 21 from being visible through the lens 16 (FIG. 3).

 The air gap 12 between the optical elements 9, 11 is designed to fulfill the conditions for the total internal reflection of the luminescent radiation 24. In addition, this luminescent radiation comes out of the ends 25, so they should be left open if possible and / or the inside of the optical sight 17 must be provided absorbing the luminescent radiation emitted from the ends 25 of the optical elements 9, 11, 24 by a coating 26, at least at the places where this luminescent radiation exits. The presence of an absorbing coating 26 with a reflection coefficient of less than 1%, operating in the wavelength range emerging from the ends 25 of the optical elements 9, 11 of the luminescent radiation 24, in the places of its exit from the ends 25 excludes the possibility of additional re-reflection of the luminescent radiation in the inner part of the optical sight 17 and, as a consequence, the possible unmasking of the latter as a result of the presence of such additional re-reflection.

 The optical elements 9, 11 can be either flat or convex. Giving the optical elements 9, 11 a convex (cylindrical or spherical) shape increases the proportion of luminescent radiation exiting from their front surface 5, and, conversely, decreases the proportion of this radiation emerging from the back surface of optical elements 9, 11 into an optical or optoelectronic device 2 or towards the eyes and face, for example, when using binoculars, a spyglass, etc.

 As the material for creating the optical elements 9, 11 activated by the phosphor 10, optical material can be used that ensures the operability of optical or optoelectronic devices 2 through the input optics 1, transparent in the visible region of the spectrum and in the region of luminescent absorption and radiation of the phosphor, for example optical glass.

 As phosphors, for example, luminescent organic dyes can be used.

 The application of a reflective coating made of one 4 or several (in the case of a multilayer reflective coating 13) layers, for example, metals with highly reflective properties, on the front surface 5 of the lens 16 along its periphery 18 with the possibility of aiming through the transparent central part 19 is carried out, for example, vacuum spraying method.

 Similarly, an additional absorbent coating 21 can be applied to the front transparent center portion 20 of the reflective lens 16.

 Similarly, on the front surface 5 and / or the reflective coating 4, 13 (on the additional absorbent coating 20 or / and the reflective coating 4, 13 of the reflective lens 16), if necessary, a protective coating 14, transparent in the working for optical and optical -electronic devices 2 areas of the electromagnetic spectrum, for example, based on aluminum oxide.

 Similarly, a coating reflecting in the wavelength region of the light source 21 can be applied to the back surface 22 of the reflective lens 16 to reflect the radiation of the light source 21 (if any) from the back surface 22 of the lens 16 and to prevent the light source 21 from being visible through the lens 16.

 If the operating conditions of optical and optoelectronic devices 2 require protection against mechanical damage (solid particles or splashes, incendiary mixtures, moving bullets and fragments, etc.), then the input reflecting element (the first along the external radiation 6) can be made in the form of a protective glass 3 (figure 1).

 The protective device of the input optics 1 of the optical and optoelectronic devices 2 operates as follows.

 The flux of external locating radiation 6 in the visible, UV and / or IR regions of the electromagnetic spectrum (for example, laser radiation) from reconnaissance and surveillance objects, for example NVDs, including optical locators, laser rangefinders, IR NVDs, etc., when scanning sectors falls on the input optics of 1 optical or optoelectronic device 2 of the IWT object, for example, the input optics of optical and optoelectronic sights (small arms, tanks, artillery and rocket launchers, etc.), aiming devices, surveillance tions, intelligence, etc. The radiation 26 reflected from the input optics of the optical and optoelectronic sights returns to the enemy’s object, conducting reconnaissance and surveillance, if necessary, is concentrated, for example, by the positive lens 27 and arrives at the sensitive area of the radiation detector 7, located near the focus of the lens 27 (if there is one) . At the time of reception from the input optics 1 of the optical or optoelectronic device 2 of the reflected radiation weapon 26 observed by means of the locating radiation 6 (for example, laser radiation) 26 receiver m 7 determined the exact location of the optical or opto-electronic device 2 IWT object.

 Then, depending on the task, the input optics 1 of the optical or optoelectronic device 2 are subjected to an IWT object, for example, by laser radiation, the power of which is sufficient for failure of the input optics 1 as a result of matting, destruction, etc., and, as a result, ensuring the failure of the optical or optoelectronic device 2 and the military hardware component as a whole.

 In the presence of a reflective coating 4 on the front surface 5 of the input reflective element 3 (for example, in the form of a protective glass; an optical reflective element 9 or a reflective lens 16), the external emission radiation 6 incident on the reflection coating 4 is reflected in the direction of the external radiation emission source 6, and if locating radiation 6 of low power, then when reflected radiation 26 enters the sensitive area of receiver 7, a bright spot appears in it, which prevents the observation of input optics 1 of optical or optical Iko-electronic device 2 of the IWT object, which in this case has a lower brightness, and, as a consequence, the determination of the exact location of the IWT object. The impact on the receiver 7 of the NVD (optical locator, laser range finder, etc.) of a sufficiently powerful intrinsic reflected radiation 26 can even lead to its failure, that is, in this case, the enemy’s own receiver equipment is hit, often using laser radiation with parameters sufficient to defeat (matting) the input optics.

 The multilayer reflective coating 13 allows you to expand the range of the reflected external radiation 6 in the direction of the source of external radiation 6, because with the appropriate selection of layers of the reflective coating 13 one of the layers provides reflection, for example, only in the visible region of the electromagnetic spectrum, remaining, for example, transparent to UV and / or IR region of the electromagnetic spectrum, another layer provides reflection, for example, only in the UV region of the electromagnetic spectrum, remaining, for example, transparent for the visible and / or infrared region of the electromagnetic spectrum, etc.

 In the presence of an input optical reflecting element 9 made of an optical material activated by a phosphor 10, the spectral absorption band of which corresponds to the spectrum of the locating radiation 6, the latter is absorbed by the luminescence centers 10. In addition, each center 10 emits luminescent radiation in all directions. Part of this radiation exits through the front and back surfaces of the reflecting element 9, however, most of the luminescent radiation due to total internal reflection begins to propagate inside the reflecting element 9 and leaves it through the side ends 25 in the form of luminescent radiation 24.

 The fraction of luminescent radiation 24 propagating inside the reflecting element 9 and emerging from its side ends 25 depends on the refractive index of the material of the reflecting element 9 (for example, for IR laser radiation 6 with a refractive index of 1.5, this fraction is 75 %

 Additional optical elements 11 work in a similar way, in which the phosphor 10 is selected so that the luminescence spectrum of the phosphor 10 of the previous optical element 9, 11 along the radiation 6 corresponds to the spectral absorption band of the phosphor 10 of the subsequent optical element 9, 11.

 The number of used additional optical elements 11 activated by the phosphor 10, and the selection of the corresponding phosphors 10 determines the degree of decrease in the brightness and power of the external locating radiation 6 in the corresponding regions of the visible, IR and UV ranges of the electromagnetic spectrum.

 An additional absorbent coating 20 (if present) with a reflection coefficient of less than 1%, for example, in the wavelength range of 420-710 nm on the front transparent central part 19 of the reflecting lens 16 eliminates the reflection of external radiation emitting 6 NVD, including optical locators, laser rangefinders , IR NVD, etc. in the corresponding range of the electromagnetic spectrum of the front transparent central part 19 of the reflective lens 16 and, as a result, reduces its visibility by the adversary during reconnaissance and surveillance.

 The protective coating 14, transparent in the working area for the optical and optical electronic devices 2 of the electromagnetic spectrum, on the front surface 5 and / or the reflective coating 4, 13 protects the additional absorbent coating 20, the reflective coating 4 and the reflective lens 16 itself from mechanical damage, for example, from damage during transportation and use of an optical or optoelectronic device 2 of an IWT object, and the impact of adverse climatic factors.

 The wiper 15 (if available and if necessary) provides for the removal of contaminants, splashes, moisture, etc. and cleaning the front surface 5 of the reflective element 9.

 The reflective coating 23 for reflecting the radiation of the light source 21 (if any) from the back surface 22 of the lens 16 provides reflection only in the wavelength range of the radiation of the light source 21 to prevent its visibility (in the interests of masking the optical or optoelectronic device 2 of the military-tactical equipment) through the lens 16, not only with the naked eye, but also the third generation NVD. For example, in the wavelength range of the radiation of the light source 21 at 560-610 nm, the reflection coefficient of the reflective coating 23 is 99.5%, in other ranges, the reflective coating 23 is transparent to ensure the operability of optical and optoelectronic devices in this transparent wavelength range for example, in the wavelength range of 410-510 nm, the transmittance of the reflective coating 23 is over 80%.

 Based on the foregoing, a new achievable technical result of the invention is.

 1. Improving the efficiency of the use of optical and optoelectronic devices in combat conditions by providing active protection of their input optics as a result of using a reflective coating deposited on the front surface of the element with the possibility of reflecting an external radiation emitting onto the reflective coating when positioning the input reflecting element in the direction of the source external locating radiation and ensuring the operability of optical and optoelectronic devices through the rest of the pros achnuyu part of the input optics, thereby neutralizing a certain time or even disabling receiving apparatus NVD opponent due to exposure to radiation with its own parameters sufficient to defeat (matting), the input optics.

2. Improving the efficiency of the use of optical and optoelectronic devices in combat conditions by providing, along with active also passive protection of the input optics as a result of using:
- a reflective coating to reflect the radiation of the light source from the back of the lens;
- a protective coating that is transparent in the working area for the optical and optical electronic devices of the electromagnetic spectrum, on the front surface and / or reflective coating;
- a wiper that removes contaminants, splashes, moisture, etc. and cleaning the front surface of the reflective element;
- an optical material activated by a phosphor for the input optical reflecting element to ensure the release of most of this radiation through the side ends of the reflecting element in the form of luminescent radiation;
- absorbing coating on the front transparent central part of the reflective lens, eliminating the reflection of external radiation and, as a result, reducing the enemy’s visibility of the output optics during reconnaissance and surveillance;
- absorbing coating in the area of the ends of the additional optical elements, eliminating the possibility of additional re-reflection of the luminescent radiation in the inner part of the optical sight and, as a result, a possible unmasking of the latter as a result of the presence of such additional re-reflection.

 3. Increasing the life of optical and optoelectronic devices in combat conditions by providing active passive protection of their input optics.

Claims (16)

 1. A protective device for the input optics of optical and optoelectronic devices, comprising an input reflective element with a reflective coating, characterized in that the reflective coating is applied to the front surface of the reflective element with the possibility of reflection of the external radiation incident on the reflective coating in the direction of the external radiation source and ensure the operability of optical and optoelectronic devices through the rest of the transparent part of the input optics.  2. The device according to p. 1, characterized in that the input reflective element is made in the form of an input optical reflective element with the possibility of ensuring the operability of optical and optoelectronic devices through the rest of the transparent part of the reflective optical element.  3. The device according to claim 2, characterized in that the input optical reflective element is made of an optical material activated by a phosphor, the spectral absorption band of which corresponds to the spectrum of the locating radiation.  4. The device according to claim 3, characterized in that an additional optical element is introduced into it, made of optical material activated by the corresponding phosphor, and installed in series with an air gap relative to the input optical reflecting element, while the luminescence spectrum of the phosphor of the latter corresponds to the absorption spectral band phosphor of an additional optical element.  5. The device according to p. 3, characterized in that additional optical elements are introduced into it, made of optical material activated by the corresponding phosphor, and installed in series with an air gap relative to each other, while the luminescence spectrum of the phosphor of the previous optical element corresponds to spectral absorption band of the phosphor of the subsequent optical element.  6. The device according to claim 5, characterized in that an absorbing coating is introduced therein, which is arranged to absorb the additional optical elements of the luminescent radiation and / or the input optical reflective element emerging from the ends, while all additional optical elements are made with open ends.  7. The device according to any one of paragraphs. 1-3, characterized in that the reflective coating is multilayer with the ability to reflect at least one corresponding layer of the reflective coating of the incident incident external radiation of various electromagnetic wavelength ranges.  8. The device according to claim 2, characterized in that a protective coating is applied to the front surface and / or the reflective coating of the reflective optical element.  9. The device according to claim 2, characterized in that the input optical reflective element is made in the form of an input reflective lens, while the reflective coating is applied to the front surface of the lens along its periphery with the possibility of ensuring the operability of optical and optoelectronic devices through the transparent central part of the lens .  10. The device according to claim 1, characterized in that the input reflective element is made in the form of a protective glass.  11. The device according to p. 2, characterized in that the reflective coating is applied to a transparent working and / or opaque non-working part of the front surface of the reflecting element.  12. The device according to p. 3, characterized in that a wiper is inserted into it, installed with the possibility of cleaning the front surface of the reflecting element.  13. The device according to p. 9, characterized in that the input reflective lens is made in the form of an input reflective lens of the optical sight, which provides aiming at the target, while the reflective coating is applied to the front surface of the said lens along its periphery with the possibility of aiming through the transparent central part lenses.  14. The device according to p. 13, characterized in that an additional absorbent coating is applied to the front transparent central part of the input reflective lens.  15. The device according to p. 14, characterized in that the additional absorbent coating and / or reflective coating of the reflective lens is coated.  16. The device according to p. 15, characterized in that a light source is additionally introduced into the optical sight, which is configured to form an image of the aiming mark on the input reflective lens when the back surface of the reflecting lens is highlighted, a coating reflecting on the back surface of the input reflective lens is applied the wavelength region of the radiation of the light source, to reflect the radiation of the light source from the back surface of the lens and to prevent the visibility of the radiation of the light source through the lens.

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