The optical image detecting apparatus according to one embodiment of the present invention may comprise a prism structure comprising a first right-angled prism and a second right-angled prism configured to be in contact with each other to form a first interface in order to transmit and reflect an image input from the outside, wherein the second right-angled prism may comprise at least two right-angled sub-prisms configured to be in contact with each other to form a second interface.

An infinity mirror includes a light-transmissible and reflective layer, a reflective layer, a light-transmissible layer and at least one light-emitting element. The light-transmissible and reflective layer is disposed on a top surface of the light-transmissible layer. The reflective layer is disposed on a bottom surface of the light-transmissible layer. The at least one light-emitting element emits a light beam. The light-transmissible layer includes a pattern zone and a non-pattern zone. There is a height difference between the pattern zone and the non-pattern zone of the light-transmissible layer. The infinity mirror can provide a multi-mirror image effect.

An image display device includes a transparent plate which may be disposed in an inclined manner with respect to a display section of a portable terminal provided with the display section. A display displayed on the display section may be reflected on the transparent plate. A space behind the transparent plate may be viewed through the transparent plate and, at the same time, an image on the display section of the portable terminal may also be viewed while being reflected on the transparent plate.

A near-eye display device is disclosed that includes a pixel display configured to display multiple groups of pixels, in each frame of image, that are output by scanning. The device includes multiple semi-reflectors, where each semi-reflector is in a one-to-one correspondence with each group of pixels displayed by the pixel display unit. Each semi-reflector includes multiple inner platings that are disposed at different reflection angles. Each of the inner platings is in a one-to-one correspondence with each pixel subunits that is in a group of pixels corresponding to a semi-reflector in which the inner plating is located. Each semi-reflector is configured to be activated when the group of pixels corresponding to the semi-reflector is reflected, and reflect each pixel subunit which is in a one-to-one correspondence with each of the inner platings to a direction of an eyeball center by using all the inner platings included in the semi-reflector.

A laser array comprises first and second laser unit to respectively emit a first and second laser beams that propagate in a first and second directions and that are polarized in first and second polarization directions and a polarization coupling prism arranged to couple the two laser beams. The coupling prism comprises: a light entry surface to receive the first laser beam; a reflecting surface to reflect the first laser beam at an angle greater than the limit angle of total inner reflection; and a light exit surface through which the first laser beam exits the prism. The second laser unit is arranged relative to the polarization coupling prism to cause the second laser beam to impinge on and be reflected at the light exit surface in the same direction as the first laser beam exiting the prism, resulting in a collinear superposition of the first and second laser beams.

A projector includes an illumination system, a biaxially-tilted digital micromirror device (DMD), a first prism, a second prism and a lens. The illumination system provides an incident light. The biaxially-tilted DMD having two opposite first long sides and two opposite first short sides receives the incident light and converts the incident light into an image light. The first prism is disposed between the illumination system and the DMD, and includes a first face and a second face connected and adjacent to the first face. The second prism is disposed between the first prism and the DMD and includes a third face, a fourth face and a fifth face; and the third face is connected and adjacent to the fourth face and fifth face. The fourth face has two opposite second long sides and two opposite second short sides. The lens receives and projects the image light.

A stereo comparator configured for use with a stereo endoscope for adjusting and aligning an optical assembly of the stereo endoscope, for example, in connection with the repair of the endoscope. The comparator includes a housing containing a plurality of optical components, namely, a first deflecting component, a second deflecting component, a third deflecting component and a beam splitter. The optical components are arranged so that the first deflecting component deflects a first beam from a right image channel of a stereo endoscope to the beam splitter, the second deflecting component deflects a second beam from a left image channel of the stereo endoscope to the third deflecting component, the third deflecting component deflects the second beam to the beam splitter and the beam splitter combines the first beam with the second beam to form a first combined beam that extends along an optical axis of the stereo endoscope.

A spectroscopic ellipsometry system and method for thin film measurement with high spatial resolution. The system includes a rotating compensator so that spectroscopic ellipsometric and imaging ellipsometric data are collected simultaneously with the same measurement beam. Collecting both ellipsometric data sets simultaneously increases the information content for analysis and affords a substantial increase in measurement performance.

A display box is capable of supporting an electronic device. The electronic device is capable of emitting an image beam. A display box includes a box, a light-transmitting plate and a pivoting carrier. The box has a top-side opening and a viewing opening. The light-transmitting plate is obliquely arranged in the box and is capable of reflecting the image beam passing through the viewing opening to a target. The pivoting carrier has an accommodating recess and a first pivot axis. The pivoting carrier is disposed on the box. The pivoting carrier is pivoted beside the top-side opening by the first pivot axis. The electronic device is disposed in the accommodating recess, wherein the pivoting carrier rotates by the first pivot axis to make the electronic device face different positions.

An optical reflective device for homogenizing light including a waveguide having a first and second waveguide surface and a partially reflective element is disclosed. The partially reflective element may be located between the first waveguide surface and the second waveguide surface. The partially reflective element may have a reflective axis parallel to a waveguide surface normal. The partially reflective element may be configured to reflect light incident on the partially reflective element at a first reflectivity for a first set of incidence angles and reflect light incident on the partially reflective element at a second reflectivity for a second set of incident angles.