An eyepiece includes a planar waveguide having a front surface and a back surface. The eyepiece also includes a grating coupled to the back surface of the planar waveguide and configured to diffract a first portion of the light propagating in the planar waveguide out of a plane of the planar waveguide toward a first direction and to diffract a second portion of the light propagating in the planar waveguide out of the plane of the planar waveguide toward a second direction opposite to the first direction and a wavelength-selective reflector coupled to the front surface of the planar waveguide. The wavelength-selective reflector comprises a multilevel metasurface comprising a plurality of spaced apart protrusions having a pitch and formed of a first optically transmissive material and a second optically transmissive material disposed between the spaced apart protrusions.

An optical element driving mechanism includes a fixed portion, a movable portion, a driving assembly, and a limiting assembly. The movable portion is connected to an optical element with an optical axis, and is movable relative to the fixed portion. The driving assembly drives the movable portion to move relative to the fixed portion. The limiting assembly is disposed on the movable portion and is connected with the driving assembly. The driving assembly is limited to move within a movable range relative to the fixed portion by the limiting assembly.

An optical assembly is for polarizing a laser beam. The optical assembly has a plurality of plate-shaped optical elements having a beam entry surface and a beam exit surface, and a holder configured to joint fix the plate-shaped optical elements. At least three spacers are arranged between each two adjacent ones of the plate-shaped optical elements. Each of the spacers is configured to provide punctiform contact with the respective beam exit surface of a first plate-shaped optical element, of the plate-shaped optical elements, and to provide punctiform contact with the respective beam entry surface of a second adjacent plate-shaped optical element, of the plate-shaped optical elements.

The disclosure relates to an optical system, for example a lithography system, comprising an aperture stop having an aperture with an edge for delimiting a beam path of the optical system on its outer circumference. The optical system also includes a heat stop arranged upstream of the aperture stop for partially shading the aperture stop. The edge of the aperture stop is excluded from the shading.

A wearable electronic device according to various embodiments disclosed herein may include: a housing, a printed circuit board on which a processor is disposed, a display module including a display, a vent hole disposed at the housing, a connection member comprising a conductor and including a vent region facing the vent hole and electrically connecting the printed circuit board and the display module, a heat dissipation member comprising a material having high thermal conductivity and disposed at the connection member and at least a part of which covers at least a part of the vent region, and a vent bracket including a vent channel connected to the vent hole and is disposed between the heat dissipation member and the vent hole.

To provide a polarizing plate capable of excellently controlling reflectance characteristics, a polarizing plate manufacturing method, and an optical apparatus including the polarizing plate. Provided is a polarizing plate 10 with a wire grid structure, including: a transparent substrate 1 and a grid-shaped convex portion 6 arranged on the transparent substrate at a pitch shorter than a wavelength of light of a use band and extending in a predetermined direction, wherein the grid-shaped convex portion 6 includes a reflection layer 2, a first dielectric layer 3, and an absorption layer 4 in order from the transparent substrate 1, and wherein the reflection layer and the first dielectric layer have substantially the same width and a minimum width of the absorption layer is smaller than a minimum width of the reflection layer and the first dielectric layer as viewed from a predetermined direction.

An optical engine module and a projection apparatus are provided. The optical engine module is adapted for a projection apparatus. The optical engine module includes a casing, an optical element, a fixing member, and a heat dissipation fin group. The optical element is disposed in the casing. The optical element has a first surface, a second surface, and a plurality of side surfaces. Each of the side surfaces is adjacent between the first surface and the second surface. The fixing member is disposed on at least one of the side surfaces of the optical element, and is configured to fix the optical element in the casing. The heat dissipation fin group is disposed on the fixing member and extends out of the casing.

An opto-mechanical assembly includes a first thermal control element disposed on a region of a first section of an enclosure; a second thermal control element disposed on a region of a second section of the enclosure; and an optical element that includes a first portion and a second portion. The first thermal control element is configured to heat the first portion of the optical element and to cause the first portion of the optical element to be associated with a first temperature, and the second thermal control element is configured to heat the second portion of the optical element and to cause the second portion of the optical element to be associated with a second temperature. This causes a difference between the first temperature and the second temperature to satisfy a temperature difference threshold. Accordingly, this also causes a temperature gradient along an axis of the optical element to satisfy a temperature gradient threshold.

An imaging apparatus is mounted on a moving object and configured to capture an image while moving along a moving direction of the moving object. The imaging apparatus includes a sensor unit including a sensor substrate on which an image sensor is mounted, and a main unit including a main substrate on which an electronic component configured to process an output signal from the sensor substrate is mounted. The imaging apparatus further includes a heat dissipation fin configured to dissipate heat generated in at least one of the sensor unit and the main unit. The heat dissipation fin is provided in a direction substantially parallel to the moving direction.

A head up display (HUD) system includes: a laser; a liquid crystal on silicon (LCoS) panel configured to modulate light output by the laser; a modulator control module configured to, during each predetermined period: apply power to the LCoS panel for a first predetermined ON period; and disconnect the LCoS panel from power for a remainder of the predetermined period; and a laser control module configured to, during each predetermined period: when a temperature of the LCoS panel is less than a predetermined temperature: apply power to the laser for a second predetermined ON period while power is applied to the LCoS panel and after the modulator control module begins applying power to the LCoS panel, where the second predetermined ON period is less than the first predetermined ON period; and disconnect the laser from power for the remainder of the predetermined period.