A method for removing satellite trails from images includes the following: obtaining an initial image having stars, locating stars in the image, removing the located stars from the initial image to form a star-removed image, locating the satellite trail in the star-removed image, determining brightness information for the satellite trail in the initial image, creating a satellite-trail-containing image with only satellite trail brightness information based on the determined brightness information, and subtracting the satellite-trail-containing image from the initial image to remove the satellite trail so as to form a satellite-trail-removed image. Systems for removing satellite trails from images are also provided, as are other aspects.

An optical imaging system employing a device containing a sequence of first (pre-dispersor) and second (main) volume holograms configured to operate as a sequence of optical diffractive elements possessing different blazing curves. A pre-cursor hologram has a thickness smaller than the thickness of the following, disperser hologram, and a comparatively broad spectral selectivity as compared to that of the main hologram, allowing the pre-cursor to diffract light in transmission within a very large range of the angles of incidence. The use of the combination of the pre-cursor and the main holograms not only implements selective imaging of the chosen target object at every angle at which various portions of the object are seen at the optical system, but also facilitates the spectroscopic measurements of such object.

An optical imaging system employing a device containing a sequence of first (pre-dispersor) and second (main) volume holograms configured to operate as a sequence of optical diffractive elements possessing different blazing curves. A pre-cursor hologram has a thickness smaller than the thickness of the following, disperser hologram, and a comparatively broad spectral selectivity as compared to that of the main hologram, allowing the pre-cursor to diffract light in transmission within a very large range of the angles of incidence. The use of the combination of the pre-cursor and the main holograms not only implements selective imaging of the chosen target object at every angle at which various portions of the object are seen at the optical system, but also facilitates the spectroscopic measurements of such object.

An occulting device includes a sensor capable of capturing an image, a photochromic film disposed in a field of view of the sensor, and a projector disposed adjacent the photochromic film and capable of darkening portions of the film.

A cloaking device with an object-side, an image-side, and a cloaked region is provided. A first object-side converging lens and a second object-side converging lens are positioned on the object-side, and a first image-side converging lens and a second image-side converging lens are positioned on the image-side. A coherent image guide with an object-side end optically aligned with the second object-side converging lens and an image-side end optically aligned with the second image-side converging lens is included. Light from an object positioned on the object-side of the cloaking device is focused in parallel onto the object-side end of the coherent image guide by the first object-side converging lens and the second object-side converging lens, propagates through the coherent image guide, and is focused in parallel by the second image-side converging lens and the first image-side converging lens to form an image of the object on the image-side of the cloaking device.

A cloaking device with an object-side, an image-side, and a cloaked region is provided. A first object-side converging lens and a second object-side converging lens are positioned on the object-side, and a first image-side converging lens and a second image-side converging lens are positioned on the image-side. A coherent image guide with an object-side end optically aligned with the second object-side converging lens and an image-side end optically aligned with the second image-side converging lens is included. Light from an object positioned on the object-side of the cloaking device is focused in parallel onto the object-side end of the coherent image guide by the first object-side converging lens and the second object-side converging lens, propagates through the coherent image guide, and is focused in parallel by the second image-side converging lens and the first image-side converging lens to form an image of the object on the image-side of the cloaking device.

An optical lens barrel having a transmissive liquid crystal display function, liquid crystal display module and display screen, wherein the optical lens barrel comprises a lens barrel body, an eye lens disposed at one end of the lens barrel body, an objective lens disposed at the other end of the lens barrel body, and an LCD display screen disposed at a focal plane position of the optical lens barrel, wherein the LCD display screen is a light scattering LCD display screen; the optical lens barrel is further internally provided with a visible light source; the position of the light source should satisfy: the light source is disposed outside a visible area of the light scattering LCD display screen.

An optical lens barrel having a transmissive liquid crystal display function, liquid crystal display module and display screen, wherein the optical lens barrel comprises a lens barrel body, an eye lens disposed at one end of the lens barrel body, an objective lens disposed at the other end of the lens barrel body, and an LCD display screen disposed at a focal plane position of the optical lens barrel, wherein the LCD display screen is a light scattering LCD display screen; the optical lens barrel is further internally provided with a visible light source; the position of the light source should satisfy: the light source is disposed outside a visible area of the light scattering LCD display screen.

Systems and devices can include a first optical element and a second optical element, the first and second optical elements transparent to visible light; and a photovoltaic element residing between the first optical element and the second optical element, the photovoltaic element transparent to visible light, the photovoltaic element to generate electricity based on the absorption of ultraviolet (UV) and near-infrared (NIR) light. The photovoltaic element can include a conductive element to conduct electricity generated from the absorption of UV and NIR light.

The invention relates to a viewing instrument (1) for observing the surroundings and aiming at targets in the surroundings of a vehicle, in particular an armored vehicle, comprising an eyepiece unit (2) and an objective unit (3) and comprising an optical waveguide bundle (4), which connects the objective unit (3) and the eyepiece unit (2) to each other, wherein the optical waveguide bundle (4) transmits an image of the surroundings, which is focused by the optical unit of the objective unit (3) onto the objective-side end of the optical waveguide bundle (4), to the eyepiece unit (2), wherein a reticle (6) is arranged in an intermediate image plane, in which the optical unit (5) of the eyepiece unit (2) focuses the transmitted image of the surroundings as an intermediate image, and is rotatable about the optical axis (7) relative to the intermediate image.