An optical device provided with an optical parts position adjusting and fixing device for adjusting and fixing the position of the optical parts moving in an optical axis direction, wherein the position adjusting and fixing device is provided with a long slotted hole extended in the optical axis direction formed on a side surface of the optical parts; a fixing means which is mounted on an object to be fixed of the optical parts and which is movable along the long slotted hole; a non-penetrating screw hole formed in the fixing means and which is divided by a slit; and a screw which is screwed into the screw hole and spreads the slit when screwed into the screw hole so as to press the outer surface of the fixing means against the inner surface of the long slotted hole.

A vehicular exterior rearview mirror assembly includes a powerfold actuator electrically operable to pivot a mirror head relative to a mounting base. The actuator includes a biasing element disposed between an upper housing and an upper end of a pivot tube and releasably retains the powerfold actuator in at least one detent state. An upper detent is disposed radially outboard of the pivot tube and radially inboard of an output gear and a lower detent, and the upper detent includes a detent lip that engages an upper detent surface of the lower detent. When the actuator is in a primary detent state, a spring load path of the biasing element is through the output gear and lower detent to the base. When the actuator is in a secondary detent state, the spring load path is through the detent lip of the upper detent and lower detent to the base.

A vehicular exterior rearview mirror assembly includes a powerfold actuator electrically operable to pivot a mirror head relative to a mounting base. The actuator includes a biasing element disposed between an upper housing and an upper end of a pivot tube and releasably retains the powerfold actuator in at least one detent state. An upper detent is disposed radially outboard of the pivot tube and radially inboard of an output gear and a lower detent, and the upper detent includes a detent lip that engages an upper detent surface of the lower detent. When the actuator is in a primary detent state, a spring load path of the biasing element is through the output gear and lower detent to the base. When the actuator is in a secondary detent state, the spring load path is through the detent lip of the upper detent and lower detent to the base.

A 3D-printed reflective optic providing very high specific stiffness through the utilization of a hollow shelled design, with closed back, filled with high-stiffness internal volumetric space-filling open-cell lattice structures. High-stiffness, structurally-integrated, sacrificial structures are also included for the purposes of reduction or elimination of tooling during post-processing operations.

A method and an apparatus for collecting powder samples in real-time in powder bed fusion additive manufacturing may involves an ingester system for in-process collection and characterizations of powder samples. The collection may be performed periodically and uses the results of characterizations for adjustments in the powder bed fusion process. The ingester system of the present disclosure is capable of packaging powder samples collected in real-time into storage containers serving a multitude purposes of audit, process adjustments or actions.

An optical member driving mechanism is provided. The optical member driving mechanism includes a first movable portion, a fixed portion, a first driving assembly, and a plurality of second guiding members. The first movable portion is configured to connect an optical member. The optical member is used for adjusting a direction of a light from an incident direction to an outgoing direction. The first movable portion can move relative to the fixed portion. The first driving assembly is configured to drive the first movable portion to move relative to the fixed portion. The second guiding members include a first ball, a second ball, and a third ball. The first ball, the second ball, and the third ball are disposed in a plane that is perpendicular to the incident direction.

An optical member driving mechanism is provided. The optical member driving mechanism includes a first movable portion, a fixed portion, a first driving assembly, and a plurality of second guiding members. The first movable portion is configured to connect an optical member. The optical member is used for adjusting a direction of a light from an incident direction to an outgoing direction. The first movable portion can move relative to the fixed portion. The first driving assembly is configured to drive the first movable portion to move relative to the fixed portion. The second guiding members include a first ball, a second ball, and a third ball. The first ball, the second ball, and the third ball are disposed in a plane that is perpendicular to the incident direction.

A vehicular interior rearview mirror assembly includes a mirror head adjustably attached at a mounting base. The mirror head includes a prismatic mirror reflective element having a wedge-shaped, reflector-coated glass substrate having a front side and a rear side separated by a thickness of the glass substrate, with the thickness of the glass substrate varying between a lower edge region of the glass substrate and an upper edge region of the glass substrate. A driver monitoring camera is accommodated by the mirror head and views through the prismatic mirror reflective element. A refraction-compensating element is disposed between a lens of the driver monitoring camera and the rear side of the glass substrate of the prismatic mirror reflective element. The refraction-compensating element is a wedge-shaped element that offsets refraction of light that passes through the wedge-shaped, reflector coated glass substrate of the prismatic mirror reflective element.

A vehicular interior rearview mirror assembly includes a mirror head adjustably attached at a mounting base. The mirror head includes a prismatic mirror reflective element having a wedge-shaped, reflector-coated glass substrate having a front side and a rear side separated by a thickness of the glass substrate, with the thickness of the glass substrate varying between a lower edge region of the glass substrate and an upper edge region of the glass substrate. A driver monitoring camera is accommodated by the mirror head and views through the prismatic mirror reflective element. A refraction-compensating element is disposed between a lens of the driver monitoring camera and the rear side of the glass substrate of the prismatic mirror reflective element. The refraction-compensating element is a wedge-shaped element that offsets refraction of light that passes through the wedge-shaped, reflector coated glass substrate of the prismatic mirror reflective element.

An adjustable optical arrangement includes an optics mount, an optical element held at the optics mount, a holding structure having a ball joint for receiving the optics mount, a ball joint holding the optics mount at the holding structure, a first adjustment device configured to pivot the optics mount with respect to the holding structure about a first axis, and a second adjustment device configured to pivot the optics mount with respect to the holding structure about a second axis. The ball joint is disposed between the optical element and the first and the second adjustment device.