The present disclosure describes a lighting system for vehicle interiors, comprising a light source that emits visible light and a component arranged relative to the light source in such a manner that light emitted from the light source passes through it. The lighting system further comprises a transparent substrate with a surface area through which light emitted from the light source passes, and a lenticular screen structure having a plurality of regularly arranged lens elements and being formed on the surface area of the transparent substrate. The invention present disclosure also describes using the lighting system and its component to illuminate the interior of vehicles, wherein generated three-dimensional lighting effects can be perceived differently by a viewer/occupant in the interior space, depending on the angle of viewing.

The present disclosure describes a lighting system for vehicle interiors, comprising a light source that emits visible light and a component arranged relative to the light source in such a manner that light emitted from the light source passes through it. The lighting system further comprises a transparent substrate with a surface area through which light emitted from the light source passes, and a lenticular screen structure having a plurality of regularly arranged lens elements and being formed on the surface area of the transparent substrate. The invention present disclosure also describes using the lighting system and its component to illuminate the interior of vehicles, wherein generated three-dimensional lighting effects can be perceived differently by a viewer/occupant in the interior space, depending on the angle of viewing.

An in-cabin monitoring system includes a camera which captures an image of an inside of a cabin of a vehicle, a light source which irradiates the inside of the cabin with light, and a controller which controls the camera and the light source. The light source is capable of emitting first light which is light to be emitted when checking whether a person is present using the camera and second light which is stronger than the first light. The controller captures an image of the inside of the cabin using the camera while causing the light source to emit the second light, before the person gets in the vehicle and after the person gets out of the vehicle.

An in-cabin monitoring system includes a camera which captures an image of an inside of a cabin of a vehicle, a light source which irradiates the inside of the cabin with light, and a controller which controls the camera and the light source. The light source is capable of emitting first light which is light to be emitted when checking whether a person is present using the camera and second light which is stronger than the first light. The controller captures an image of the inside of the cabin using the camera while causing the light source to emit the second light, before the person gets in the vehicle and after the person gets out of the vehicle.

In a method for producing a light program (22) for controlling lighting in an interior (80) of an aircraft (82) during a flight, a sequence list (2a, b) of phases of the day (4a-l) for a full day is set, wherein a time of day (6), a phase duration (8) and lighting data (La-l) for the lighting are assigned to each phase of the day (4a-l), the appropriate phase of the day (4a-l) is selected from the sequence list (2a, b) as first program section (14a) of a flight program (10) on the basis of the local time (12a) at which the flight starts and the proportional associated phase duration (8) is assigned to the first program section as section duration (16a), the appropriate phase of the day (4a-l) is selected from the sequence list (2a, b) as last program section (14b-e) of the flight program on the basis of the local time (12b) at which the flight lands and the proportional associated phase duration (8) is assigned to the last program section (14b-e) as section duration (16b-e), the flight program (10) between first program section (14a) and last program section (14b-e) is filled with the phases of the day (4a-l), lying therebetween as per the sequence list (2a, b), as program sections (14b-d) and the associated phase durations (8) are assigned to the program sections (14b-d) as section durations (16b-d), at least one of the section durations (16a-e) is scaled on the basis of a scaling prescription in such a way that the overall duration of the flight program (10) corresponds to the flight duration (TF), the flight program (10) runs in time during the flight on the basis of the elapsed flight time (t), wherein the lighting data (La-l) of the respective current program section (14a-e) are output as light program (22) at each instant of the flight time (t).

In a method for producing a light program (22) for controlling lighting in an interior (80) of an aircraft (82) during a flight, a sequence list (2a, b) of phases of the day (4a-l) for a full day is set, wherein a time of day (6), a phase duration (8) and lighting data (La-l) for the lighting are assigned to each phase of the day (4a-l), the appropriate phase of the day (4a-l) is selected from the sequence list (2a, b) as first program section (14a) of a flight program (10) on the basis of the local time (12a) at which the flight starts and the proportional associated phase duration (8) is assigned to the first program section as section duration (16a), the appropriate phase of the day (4a-l) is selected from the sequence list (2a, b) as last program section (14b-e) of the flight program on the basis of the local time (12b) at which the flight lands and the proportional associated phase duration (8) is assigned to the last program section (14b-e) as section duration (16b-e), the flight program (10) between first program section (14a) and last program section (14b-e) is filled with the phases of the day (4a-l), lying therebetween as per the sequence list (2a, b), as program sections (14b-d) and the associated phase durations (8) are assigned to the program sections (14b-d) as section durations (16b-d), at least one of the section durations (16a-e) is scaled on the basis of a scaling prescription in such a way that the overall duration of the flight program (10) corresponds to the flight duration (TF), the flight program (10) runs in time during the flight on the basis of the elapsed flight time (t), wherein the lighting data (La-l) of the respective current program section (14a-e) are output as light program (22) at each instant of the flight time (t).

According to one aspect of the present invention, a light assembly of a vehicle is provided herein. The light assembly includes an array of light sources and a plurality of light-directing elements, each configured to direct light received from the light sources in an associated direction. A sensor arrangement is configured to sense a user-supplied action and a controller determines which light sources to activate in response to the sensed user-supplied action.

According to one aspect of the present invention, a light assembly of a vehicle is provided herein. The light assembly includes an array of light sources and a plurality of light-directing elements, each configured to direct light received from the light sources in an associated direction. A sensor arrangement is configured to sense a user-supplied action and a controller determines which light sources to activate in response to the sensed user-supplied action.

An illuminating device for a vehicle includes a carrier module, a flat light guide attached to the carrier module with a plurality of emitting points, and multiple light sources for illuminating the light guide. The flat light guide is concealed with a translucent haptic layer, which is attached to a visible side of the light guide, which, in turn, is covered by a decorative layer. The illuminating device comprises a rope-like light guide, which has an inherent light source and is connected to the decorative layer via a retaining device. This therefore results in a flat arrangement, which can be easily integrated into the interior parts and simultaneously enables illumination over a large surface area. In doing so, additional light effects can be integrated by means of the rope-like light guide. The illuminating device is not visible while switched off, as the illuminating device is covered by the decorative layer.

A lighting system for a motor vehicle includes a printed circuit board equipped with light emitting diodes for emitting light beams in lighting directions and an optical module formed to propagate and transmit the light beams. The optical module has a reception surface to receive the light beams and an emission surface for retransmitting the light beams. The lighting system also includes at least one element for masking the light beams emitted by the light emitting diodes. The element for masking which extends from at least one of the light emitting diodes toward the reception surface and substantially parallel to the lighting direction of the at least one light emitting diode, over at least a part of the periphery of the at least one light emitting diode and over at least a part of a distance separating the at least one light emitting diode and the reception surface.