A virtual visor system is disclosed that includes a visor having a plurality of independently operable pixels that are selectively operated with a variable opacity. A camera captures images of the face of a driver or other passenger and, based on the captured images, a controller operates the visor to automatically and selectively darken a limited portion thereof to block the sun or other illumination source from striking the eyes of the driver, while leaving the remainder of the visor transparent. The visor system advantageously predicts future positions of the head or eyes of the driver when the driver’s head is in motion. Based on the predictions, the optical state of the visor is updated proactively to anticipate future movements of head of the driver. In this way, some of the negative effects of measurement and processing latencies are mitigated when responding to rapid head motions.

A virtual visor system is disclosed that includes a visor having a plurality of independently operable pixels that are selectively operated with a variable opacity. A camera captures images of the face of a driver or other passenger and, based on the captured images, a controller operates the visor to automatically and selectively darken a limited portion thereof to block the sun or other illumination source from striking the eyes of the driver, while leaving the remainder of the visor transparent. The virtual visor system advantageously adopts a gradient blocking mode for the optical state of the visor that includes a blocker and a transition gradient, which has the effect of making updates to optical state of the visor less distracting. Additionally, the transition gradient in the optical state of the visor makes the virtual visor system more robust against errors in positioning the blocker on the visor.

A virtual visor system is disclosed that includes a visor having a plurality of independently operable pixels that are selectively operated with a variable opacity. A camera captures images of the face of a driver or other passenger and, based on the captured images, a controller operates the visor to automatically and selectively darken a limited portion thereof to block the sun or other illumination source from striking the eyes of the driver, while leaving the remainder of the visor transparent. The virtual visor system advantageously snaps projected eye positions on the visor to a grid, which helps to minimize rapid and distracting changes in the optical state of the visor.

A viewing port for sighting through a barrier includes a primary body and a secondary body engaging with a barrier aperture in the barrier. The primary body defines a first aperture. The secondary body defines a second aperture. The first aperture of the primary body is aligned with the second aperture of the secondary body defining a viewing channel between the primary body and the secondary body. The viewing channel providing a field of view through the barrier.

A sun visor assembly for a vehicle according to an exemplary aspect of the present disclosure includes, among other things, a visor configured to be mounted in a vehicle and pivotable between a first position and a second position. A display is mounted on the visor. The display is pivotable between a stowed position and a viewing position relative to the visor.

The invention relates to an extendable sun visor for a vehicle, comprising a base plate for providing a base area of shadowing, a first movable plate which is connected to the base plate and which is movable in relation to the base plate for providing a first additional area of shadowing, at least one second movable plate which is connected to the base plate and which is movable in relation to both the base plate and the first movable plate for providing at least one second additional area of shadowing, the at least one second additional area of shadowing being different from said first additional area of shadowing, and an actuating structure for actuating a movement of the at least one second movable plate when the first moveable plate is moved. A vehicle comprising such an extendable sun visor is also provided.

A sun visor assembly for a vehicle according to an exemplary aspect of the present disclosure includes, among other things, a visor having a transparent portion and a circuit configured to control at least one function of the visor. The visor is pivotable between a first position and a second position.

The problem relates to an arrangement for a flexible flat component which comprises a front side and a rear side, wherein the arrangement comprises a flat stabilization element and lamellas, wherein the lamellas are arranged on the rear side of the component, wherein the component can be deformed, wherein the stabilization element is designed to cooperate with the lamellas on the rear side of the component and to fix the component in a shape that the respective component is respectively currently in.

An illumination unit for an interior chamber of a vehicle includes at least one light source integrated into a surface side of a sun shield facing towards an occupant in a non-usage position of the sun shield. The at least one light source emits light in the activated state which is directed towards the occupant. A covering element is provided for covering a light outlet surface of the light source.

A vehicle compartment for a vehicle includes a screen through which an occupant can view portions of the environment ambient of said vehicle compartment, at least one panel, adapted to adjust the light intensity of light falling into said vehicle compartment via at least a portion of said screen, a light sensor and a control unit adapted to adjust the panel to thereby adjust the light intensity of light falling into said vehicle compartment in response to a signal issued from the light sensor.