A micro-electronic non-landing mirror system includes a substrate, at least two supporting assemblies, at least two driving electrodes, a rotating mirror, and a driving circuit. The rotating mirror is elastically supported on the supporting assemblies through elastic reset assemblies. When the driving circuit applies a driving voltage, the rotating mirror moves closer to the driving electrode to which the driving voltage is applied within a range of movement that does not land on the substrate. When the driving circuit removes the driving voltage, the rotating mirror gets back to move away from the driving electrode under elastic restoring force of the elastic reset assemblies. Each elastic reset assembly includes at least two elastic reset units connected to different corners of the rotating mirror by a corresponding one supporting assembly. Each elastic reset unit is configured for providing the rotating mirror with at least two rotational degrees of freedom.

A convex integrated vehicle inspection and security system embodying a convex parabolic mirror placed at a 45-degree angle and operatively associated with an image capture device capable of capturing a series of image strips at frame rates of up to 900/second. The single image capture device collects light and images using the convex mirror such a way that the composite image of the image strips can be presented as a panoramic image, wherein the panoramic image is displayed as a rectangle where the horizontal direction represents the width of the undercarriage of the vehicle.

A mechanically tunable reflective metamirror optical device for a targeted design optical wavelength includes a dynamically deformable substrate and a sub-wavelength periodic arrangement of patterned isolated gap surface plasmon (GSP) resonators positioned in or on the dynamically deformable substrate. The patterned isolated GSP resonators are movable relative to each other and comprise a patterned optically thin metal layer for the design wavelength, a patterned optically thick metal layer for the design wavelength, and a patterned insulator layer between the patterned optically thin and optically thick metal layers.

A mechanically tunable reflective metamirror optical device for a targeted design optical wavelength includes a dynamically deformable substrate and a sub-wavelength periodic arrangement of patterned isolated gap surface plasmon (GSP) resonators positioned in or on the dynamically deformable substrate. The patterned isolated GSP resonators are movable relative to each other and comprise a patterned optically thin metal layer for the design wavelength, a patterned optically thick metal layer for the design wavelength, and a patterned insulator layer between the patterned optically thin and optically thick metal layers.

The invention relates to an actuator mechanism (1) for adjusting the orientation of a mirror element in an exterior mirror unit of a vehicle. The mechanism comprises an electric motor (9, 10) with a driving shaft (11, 12), a drive train (13, 14), and a movable mirror adjusting element (5, 6) coupled via the drive train to the driving shaft of the electric motor. Also, the actuator mechanism comprises an actuator frame (2) which carries the electric motor, the drive train and the mirror adjusting element. The driving shaft of the electric motor is bearing mounted in the actuator frame.

The invention relates to an actuator mechanism (1) for adjusting the orientation of a mirror element in an exterior mirror unit of a vehicle. The mechanism comprises an electric motor (9, 10) with a driving shaft (11, 12), a drive train (13, 14), and a movable mirror adjusting element (5, 6) coupled via the drive train to the driving shaft of the electric motor. Also, the actuator mechanism comprises an actuator frame (2) which carries the electric motor, the drive train and the mirror adjusting element. The driving shaft of the electric motor is bearing mounted in the actuator frame.

An optical assembly is disclosed. The optical assembly includes a collimating lens which collimates a divergent laser beam. A conical mirror has a reflecting cover surface and deforms a laser beam, which propogates in the direction of the conical axis, into an annular beam in a propogation plane perpendicular to the conical axis. An optics carrier has a first carrier element on which the collimating lens is fixed and a second carrier element on which the conical mirror is fixed. A connection device has at least one connection element which connects the first and second carrier elements to one another. The at least one connection element is arranged askew to the conical axis of the conical mirror.

An optical assembly is disclosed. The optical assembly includes a collimating lens which collimates a divergent laser beam. A conical mirror has a reflecting cover surface and deforms a laser beam, which propogates in the direction of the conical axis, into an annular beam in a propogation plane perpendicular to the conical axis. An optics carrier has a first carrier element on which the collimating lens is fixed and a second carrier element on which the conical mirror is fixed. A connection device has at least one connection element which connects the first and second carrier elements to one another. The at least one connection element is arranged askew to the conical axis of the conical mirror.

An imaging system for creating an image of a target object comprising a mirror mounted on a gimbal and arranged to rotate about at least one axis, a gimbal drive unit configured to control the orientation of the gimbal, and a camera having its optical axis directed onto the mirror in order that an image reflected in the mirror is within a field of view of the camera, wherein the control unit is arranged to position the gimbal such that a reflection of a target object is within a field of view of the camera.

A first supporting unit configured to movably support, in a direction intersecting with A length direction of A first reflecting mirror, an end of the first reflecting mirror in the length direction of the first reflecting mirror; a second supporting unit configured to movably support, in a direction intersecting with the length direction of a second reflecting mirror, an end of the second reflecting mirror in the length direction of the second reflecting mirror; a first drive source; a first transmission unit configured to transmit, when the first drive source provides a drive source in a first direction, the movement of the first drive source to a first supporting unit; and a second transmission unit configured to transmit, when the first drive source provides a drive source in a second direction, a movement of a second drive source to the second supporting unit.