A display apparatus of the present disclosure includes: a first optical system that generates illumination light whose light emitting luminance is variable; a light modulation unit that transmits the illumination light from the first optical system and whose transmissivity is variable; a second optical system that includes a light modulation device and optically modulates the illumination light from the first optical system by using a pulse width modulation technology, the illumination light having passed through the light modulation unit; and a control unit that controls the light emitting luminance of the illumination light from the first optical system and the transmissivity of the light modulation unit in any combination.

Provided are a composition for a light transmittance control film, and a light transmittance control film. According to the inventive concept, the light transmittance control film includes a matrix part including a copolymer and a polymer chain which is grafted to the copolymer; and a dispersed part including a polymer derived from a first monomer, and are provided in the matrix part, wherein the polymer chain is derived from the first monomer, first light transmittance is shown while external force is applied, and second light transmittance which is greater than the first light transmittance may be shown after the external force is removed.

An apparatus for optically measuring a distance to a target object which is embodied as a scattering target object or a reflecting target object. The apparatus has a distance measuring device and an adjustment device. In the distance measuring device, a laser beam is generated which is adjusted with the aid of the adjustment device to an external optical unit. The adjustment device includes a beam shaping optical unit and a focal shift device.

Systems and methods are disclosed for dynamically controlling laser pulses being output from a laser system. An example surgical system comprises a laser, an optical switching device, an adjustable input device such as a foot pedal, and a laser pulse controller. An operator actuates the adjustable input device over an operating range to control dynamically the laser pulses being output from the laser system. In one mode, the adjustable input device may dynamically control output laser energy. In another mode, the adjustable input device may dynamically control selection of laser pulses to be output from the system.

Systems and methods provide technology for a tunable vehicle window system to adjust a view for a window. The technology includes a window assembly comprising a tunable optical metamaterial deployed on a surface of a window, the tunable optical metamaterial including a transparent electroactive substrate having disposed thereon an optically active particle array, the optically active particle array including resonators having elongated members arranged in two or more orientations. The technology includes a controller to receive a signal from a photosensor indicative of a condition of incoming light to the vehicle, determine a change in a view for the window assembly based on the received photosensor signal, and control a voltage applied to the substrate to selectively expand or contract the substrate within a plane substantially parallel to the window surface and in a manner to adjust the view for the window assembly according to the determined view change.

One embodiment of a method for restricting laser beams entering an aperture to a chosen dyad and measuring their separation. The method works with frequency-modulated coherent light, and one embodiment uses a moveable, variable-aperture apparatus (FIG. 1) in conjunction with a converging lens (6) and a detector (7). Key elements of other embodiments are described.

A polarizing rotation device including a rotation shaft, a driving element and a polarizing element is provided. The driving element is configured to drive the rotation shaft to rotate. The polarizing element is connected to the rotation shaft and is disposed on a transmission path of at least one beam, where the driving element is configured to drive the polarizing element to rotate sequentially while taking the rotation shaft as a rotation central axis, and when the polarizing element is rotated, the at least one beam penetrates through the polarizing element, and the at least one beam penetrating through the polarizing element has different polarization states at different time. Therefore, when a projection device is in a polarized stereoscopic mode, a color or brightness of a display image is uniform, and a user observes a 3D display image with good uniformity.

A privacy glass vision panel assembly includes a fixed first transparent panel having a plurality of spaced vertical non-transparent lines disposed between spaced vertical transparent lines. A movable second transparent panel is disposed next to the fixed first transparent panel and includes a plurality of spaced vertical non-transparent lines disposed between spaced vertical transparent lines. A bearing system supports the movable second transparent panel relative to the fixed first transparent panel. A first magnet unit is secured to the movable second vision panel and a second magnet unit is secured to and movable relative to the fixed first transparent panel in proximity to the first magnet unit to cause movement of the movable second transparent panel when the second magnet unit is moved relative to the fixed first transparent panel.

An aspect relates to an optical limiter (200) for limiting the radiant flux of an optical source beam, comprising: an optical control port (221) for illumination by an optical control beam originating from the source beam; an optical input port (221) for illumination by an optical transmission beam originating from the source beam; an optical output port (225) for illumination by the transmission beam; and a thermally driven light mill (211, 212); wherein the light mill is arranged with respect to the input port, the control port and the output port such that illumination of the control port by the control beam drives the light mill to rotate only when the control beam has a radiant flux equal to or in excess of a predetermined radiant flux threshold; and rotation of the light mill causes an area of the output port illuminated by the transmission beam to change.

The present disclosure relates to a filter unit, a filter selection method, and an imaging device that allow continuously changing a transmittance of an ND filter and switching between filters to be performed more easily. A disk provided with a plurality of filters including an ND filter having a continuously variable transmittance is rotated to cause a filter corresponding to a rotational orientation of the disk among the plurality of filters provided on the disk to be arranged on an optical axis of incident light toward an image sensor. The present disclosure can be applied to, for example, a filter unit, an imaging device, electronic equipment, a filter selection method, a program, or the like.