A lens barrel including a space-saving position adjustment function. The lens barrel constitutes a part of a projection optical system including a catoptric system including at least one reflecting mirror and that uses a dioptric system including multiple lens groups. At least one of the multiple lens groups includes a non-circular lens. The lens barrel includes a movable part that has an inner wall surface holding the non-circular lens and that is able to move the lens group that includes the non-circular lens in an optical axis direction of the non-circular lens, a holding part that is disposed on an outer circumferential side of the movable part and that holds the movable part and a shaft part formed in the optical axis direction, and a curved part that is disposed on an outer circumferential side of the holding part.

Exemplary testing systems and methods are provided including a system configured to test for thermal drift of a unit under test (UUT) under various temperature or environmental conditions and generating an output including visual or data on the thermal drift, if any. The methods involve attaching a UUT to a mounting device within a thermally controlled chamber, collimating light received from a UUT, recording the resulting images, and comparing the results at different temperatures to determine how much thermal drift has occurred. In addition, there are testing apparatuses capable of performing the tests.

The present disclosure relates to an optical field and more particularly, to a multi-field of view (FOV) (zooming) optical assembly for a lens and may include an optical element provided in a form of a solid main optical element and including an integrated focal system with two mirrors and at least one integrated afocal system with two mirrors, a plurality of switching optical elements (SOEs) arranged on a front face of the optical element and configured to be switched between an open state in which light is transmitted and a closed state in which light is reflected and/or inhibited, and an image plane curvature correction element.

Apparatuses and systems for a die-integrated aspheric mirror are described herein. One apparatus includes an ion trap die including a number of ion locations and an aspheric mirror integrated with the ion trap die.

A freeform surface off-axial three-mirror imaging system comprising a primary mirror, a secondary mirror, a tertiary mirror, and a detector. The secondary mirror defines a first location and a second location. Each reflective surface of the primary mirror, the secondary mirror and the tertiary mirror is an xy polynomial freeform surface. A working distance of the freeform surface off-axial three-mirror imaging system is greater than 125 mm.

A multifocal rain sensor includes: at least one light emitting unit configured to output light; a first reflective plate corresponding to the at least one light emitting unit and disposed at a position spaced apart from the at least one light emitting unit by a predetermined distance; a glass part reflecting light after the light is reflected by the first reflective plate and forming a sensing region; a second reflective plate re-reflecting the light reflected by the glass part; and a light receiving unit configured to receive the light reflected by the second reflective plate. The second reflective plate includes a multifocal reflective plate having a plurality of focuses based on a vertical height of incident light that varies according to a change in thickness of the glass part.

A cata-dioptric optical system for high resolution imaging in visible and infrared bands. The system includes a concave primary mirror, a convex secondary mirror, at least one beam splitter, a first folding mirror, a first group of lenses, a second group of lenses, and at least two image planes. The image planes have one or more aggregated sensors, where a first image plane receives rays from the first group of lenses and a second image plane receives rays from the second group of lenses, and at least one image plane is positioned behind the primary mirror and at a radial distance from the optical axis that is no more than the radius of the primary mirror.

A digital exposure apparatus includes a lens array, the lens array at least including a first lens unit and a second lens unit, a light transposition assembly arranged on an exit light path of the second lens unit, and the light transposition assembly being used for controlling a light exiting from the second lens unit to be transposed with respect to an exposure direction of the digital exposure apparatus. When the digital exposure apparatus is used for exposure, a light passing through the first lens unit and a light penetrating through the second lens unit are needed to expose the same position for multiple times.

A method for adjusting the magnification scale of an optical imaging device for exposing or inspecting substrates is provided. The optical imaging device includes a first optical element group, which includes a plurality of first optical elements in an imaging beam path. The method includes replacing optical elements of the first optical element group in the imaging beam path by optical elements of a second optical element group for the purposes of adjusting the magnification scale. The first optical element group includes two reflecting optical elements with first optical parameters, which define a first Petzval sum. The second optical element group includes two reflecting optical elements with second optical parameters, which define a second Petzval sum. The value of the first Petzval sum is at least substantially identical to the value of the second Petzval sum.

An off-axis three-mirror optical system with freeform surfaces comprised an aperture, a primary mirror, a secondary mirror, a tertiary mirror, and a detector. The aperture is located on an incident light path. The primary mirror is located on an aperture side. The secondary mirror is located on a primary mirror reflected light path.

The tertiary mirror is located on a secondary mirror reflected light path. The detector located on a tertiary mirror reflected light path. The primary mirror and the tertiary mirror have a same fifth-order polynomial freeform surface expression. The primary mirror reflected light path, the secondary mirror reflected light path and the tertiary mirror reflected light path overlap with each other.