A rear backup sideview mirror assembly to be used in conjunction with a vehicle's interior rearview mirrors to view other motor vehicles moving in a side to lateral direction. The rearview mirror assembly, located on the rear of the vehicle that allows the user to see laterally away from the vehicle in both directions for oncoming obstructions and down behind the vehicle in order to observe objects that may not appear in the rearview mirror but are behind the vehicle.

A cloaking device includes an object-side, an image-side, an object-side curved cloaking region (CR) boundary having an outward facing mirror surface and an inward facing surface, and an image-side curved CR boundary an outward facing mirror surface and an inward facing surface. A cloaked region is bounded by the inward facing surfaces of the object-side curved CR boundary and the image-side curved CR boundary. At least one exterior boundary with an inward facing mirror surface is spaced apart from the object-side curved CR boundary and the image-side curved CR boundary. Light from an object positioned on the object-side of the cloaking device and obscured by the cloaked region is redirected around the cloaked region to form an image of the object on the image-side of the cloaking device such that the light from the object appears to pass through the CR.

A cloaking device includes object-side and image-side curved cloaking region boundaries with outward facing mirror surfaces and inward facing opaque surfaces. A cloaking region is bounded by the inward facing opaque surfaces of the object-side and image-side curved CR boundaries. An object-side curved reflection boundary with an inward facing mirror surface is positioned proximate to the object-side curved cloaking region boundary and an image-side curved reflection boundary with an inward facing mirror surface is positioned proximate to the image-side curved cloaking region boundary. Light from an object located on the object-side of the cloaking device and obscured by the cloaking region is redirected around the cloaking region by the outward facing mirror surfaces of the object-side and image-side curved cloaking region boundaries and the inward facing mirror surfaces of the object-side and image-side curved reflection boundaries.

A system for a vehicle (13) having a driver's cabin (15) and a rearward extending portion (14) that is pivotable with respect to the driver's cabin (15), for capturing a rear part (17) of the rearward extending portion (14), the system having at least two wheel sensors (2, 3) located on opposite ends of an axis (18, 19) of the rearward extending portion (14), for acquiring information on a rotational movement of wheels attached to the ends of the axis (18, 19), and a control unit (4) connected with the wheel sensors (2, 3), which control unit determines the rear part (17) of the rearward extending portion (14) based on the acquired information on the rotational movement of the wheels.

An optical device displaying an image of a blind spot includes a blind spot-side outward mirror disposed on a blind spot-side of a line of sight with respect to an obstacle; a blind spot-side inward mirror disposed to face the blind spot-side outward minor; an eye point-side inward mirror disposed on an eye point-side of the line of sight with respect to the obstacle; and an eye point-side outward minor disposed to face the eye point-side inward mirror. Each of the blind spot-side inward mirror and the eye point-side inward mirror has a plurality of reflection surfaces, and the reflection surfaces are arranged in parallel with each other and arranged at positions where the reflection surfaces partially overlap with each other.

Asymmetric sectioned mirrors are presented. The mirrors include, for example, constant radius of curvature sections that are selected to increase the sizes and improve the definitions of images, for example images of children milling, walking and/or standing about either the front or alongside regions of a school bus. The mirrors may be asymmetric in either or both the horizontal and vertical directions. The mirrors may include a mounting system capable of using both ball mounts and tunnel mounts.

A collision warning system including a vehicle with a first sensor configured to detect an exit condition, a second sensor configured to detect a collision condition, an external warning signal system configured to emit a warning signal to warn a vehicle occupant about the collision condition, the external warning signal system includes at least one warning device configured to emit the warning signal, and a controller configured to communicate with the first and second sensors and to control the at least one warning device in response to the collision condition.

A cloaking device includes cloaking region boundary planes oriented non-planar to each other, each of the cloaking region boundary planes having an outward facing mirror surface and an inward facing opaque surface. The cloaking device includes a cloaking region bounded at least partially by the inward facing opaque surfaces of the cloaking region boundary planes. Light from an object positioned on the object-side of the cloaking device and obscured by the CR has a first optical path through the cloaking device and light from the object not obscured by the CR has a second optical path through the cloaking device. A first matching medium is positioned between the object-side and the image-side in the second optical path and increases the second optical path length such that an optical path difference between the first optical path length and the second optical path length is reduced.

A cloaking device includes object-side and image-side curved cloaking region boundaries with outward facing mirror surfaces and inward facing opaque surfaces. A cloaking region is bounded by the inward facing opaque surfaces of the object-side and image-side curved CR boundaries. An object-side curved reflection boundary with an inward facing mirror surface is positioned proximate to the object-side curved cloaking region boundary and an image-side curved reflection boundary with an inward facing mirror surface is positioned proximate to the image-side curved cloaking region boundary. Light from an object located on the object-side of the cloaking device and obscured by the cloaking region is redirected around the cloaking region by the outward facing mirror surfaces of the object-side and image-side curved cloaking region boundaries and the inward facing mirror surfaces of the object-side and image-side curved reflection boundaries.

A cloaking device includes cloaking region boundary planes oriented non-planar to each other, each of the cloaking region boundary planes having an outward facing mirror surface and an inward facing opaque surface. The cloaking device includes a cloaking region bounded at least partially by the inward facing opaque surfaces of the cloaking region boundary planes. Light from an object positioned on the object-side of the cloaking device and obscured by the CR has a first optical path through the cloaking device and light from the object not obscured by the CR has a second optical path through the cloaking device. A first matching medium is positioned between the object-side and the image-side in the second optical path and increases the second optical path length such that an optical path difference between the first optical path length and the second optical path length is reduced.