An image capturing apparatus comprises an image sensor for capturing a subject image, a focus detection unit configured to, based on an image signal obtained by photoelectrically converting the subject image while performing a scan operation that causes a focus lens to move along an optical axis, calculate a focus evaluation value and detect a position of the focus lens at which the focus evaluation value is a maximum, and a calculation unit configured to, in a case where the imaging optical system includes a reflective optical system, calculate, based on information on the reflective optical system and information on an image forming position for each of a plurality of different spatial frequencies, a correction value for correcting a focus detection result of the focus detection unit.

A variety of femtoprojector optical systems are described. Each of them can be made small enough to fit in a contact lens using plastic injection molding, diamond turning, photolithography and etching, or other techniques. Most, but not all, of the systems include a solid cylindrical transparent substrate with a curved primary mirror formed on one end and a secondary mirror formed on the other end. Any of the designs may use light blocking, light-redirecting, absorbing coatings or other types of baffle structures as needed to reduce stray light.

An optical arrangement is provided. The optical arrangement has a center axis, an object side, an image side, and a catadioptric arrangement. The optical arrangement has an installation space of no more than 25 millimeters from the object side to the image side along the center axis, and a linear obscuration of no more than 60 percent.

An optical arrangement having a center axis, an object side, an image side, and a catadioptric arrangement is provided. The catadioptric arrangement includes first and second partly reflective optical components, the first optical component including radially inner and radially outer regions, the inner region being configured to be transparent to light incident from the object side, and the outer region being configured to reflect light incident from the object side, the second optical component including a radially inner region and a radially outer region, the outer region being configured to be transparent to light incident from the object side, and the inner region being configured to be transparent to light incident from the object side and to reflect light incident from the image side. At least one further optical component with positive refractive power is arranged at the inner region of the second optical component on the object side.

An imaging system includes a metering structure and a plurality of foldable members disposed around a periphery of the metering structure. Each foldable member in the plurality of foldable members includes an arm comprising a strain deployable composite and a reflector disposed on the arm. The arm in a respective foldable member in the plurality of foldable members is configured to hold the respective foldable member toward the metering structure in a first state and to hold the respective foldable member away from the metering structure in a second state such that the reflector of the respective foldable member forms part of a sparse aperture in the second state.

An imaging apparatus, an unmanned moving object, an imaging method, a system, and a program capable of favorably compositing a telephoto image group even in a case where an overlapping region between images of the telephoto image group is small, and accurately compositing a telephoto image regardless of a subject (scene) of a wide angle image are provided. An imaging apparatus (100) includes an imaging optical system, a directional sensor, a wide dynamic range image generation part (302) that generates a wide dynamic range wide angle image obtained by enlarging a dynamic range of a wide angle image, an image acquisition part (2a) that acquires a wide dynamic range wide angle image group and a telephoto image group configured with a telephoto image, a composition information acquisition part (2b) that acquires composition information to be used for compositing the telephoto image group by analyzing the acquired wide dynamic range wide angle image group, and a composite image generation part (2c) that generates an image in which the telephoto image group is composited, based on the composition information, information related to focal lengths of the wide angle optical system and the telephoto optical system, and the telephoto image group.

A holographic weapon sight with a low profile collimator has a housing with a viewing end and an opposed target end. The holographic weapon sight has a light source operable to project a light beam along a light path. The low profile collimator has a first optical element and a second optical element disposed in the light path of the light beam such that the second optical element provides a fully collimated light beam. The holographic weapon sight also has a first diffractive optical element (DOE), a second DOE, and a mirror. The first DOE or the second DOE reconstructs an image of a reticle and respectively reflects the reconstructed image toward the mirror or the NDE such that a user views a target along a viewing path through the NDE from the viewing end.

The present disclosure discloses a camera apparatus including a first optical system and a second optical system. The second optical system includes a secondary reflecting mirror, a main reflecting mirror with an opening in a center area thereof, and a lens group, which are sequentially arranged from an object side to an image side. Light from the object side is sequentially reflected by the main reflecting mirror and the secondary reflecting mirror, and then enters the lens group through the opening. A total effective focal length F1of the first optical system and a total effective focal length F2 of the second optical system satisfy: F2/F1>10.

An optical system includes a plurality of internal apertures, a plurality of external optical assemblies and a telescope assembly positioned between the plurality of internal apertures and the plurality of external optical assemblies. Each internal aperture is operable to receive a corresponding aperture-specific optical signal. Each external optical assembly corresponds to one of the internal apertures, and each external optical assembly is operable to direct the aperture-specific optical signal of the corresponding internal aperture in a corresponding external direction. The external direction for each external optical assembly is independently controllable and the telescope assembly defines a shared optical train arranged to direct the aperture-specific optical signals between each internal aperture and the corresponding external optical assembly.

An optical system includes a plurality of internal apertures, a plurality of external optical assemblies and a telescope assembly positioned between the plurality of internal apertures and the plurality of external optical assemblies. Each internal aperture is operable to receive a corresponding aperture-specific optical signal. Each external optical assembly corresponds to one of the internal apertures, and each external optical assembly is operable to direct the aperture-specific optical signal of the corresponding internal aperture in a corresponding external direction. The external direction for each external optical assembly is independently controllable and the telescope assembly defines a shared optical train arranged to direct the aperture-specific optical signals between each internal aperture and the corresponding external optical assembly.