Systems, apparatus and methods may be configured to implement actively-controlled light emission from a robotic vehicle. A light emitter(s) of the robotic vehicle may be configurable to indicate a direction of travel of the robotic vehicle and/or display information (e.g., a greeting, a notice, a message, a graphic, passenger/customer/client content, vehicle livery, customized livery) using one or more colors of emitted light (e.g., orange for a first direction and purple for a second direction), one or more sequences of emitted light (e.g., a moving image/graphic), or positions of light emitter(s) on the robotic vehicle (e.g., symmetrically positioned light emitters). The robotic vehicle may not have a front or a back (e.g., a trunk/a hood) and may be configured to travel bi-directionally, in a first direction or a second direction (e.g., opposite the first direction), with the direction of travel being indicated by one or more of the light emitters.

A detection is made as to whether a vehicle occupant seated on a vehicle seat of a seating system of a motor vehicle has put on a pair of electronic data glasses. If the vehicle occupant has put on a pair of electronic data glasses, a check is performed to determine whether a predetermined minimum distance exists between the vehicle seat and an interior component of the motor vehicle. If the minimum distance exists, an adjustment range of the seating system is restricted in such a way that it is not possible to fall below the minimum distance. If the minimum distance does not exist, the minimum distance is established by automatically adjusting the seating system and/or outputting a message relating to the noncompliance with the minimum distance.

A vehicle safety system for helping to protect an occupant of a vehicle seat includes a seatbelt extensible around the occupant to help restrain the occupant in the vehicle seat. The seatbelt includes a lap belt configured to extend across the occupant at the hips. An airbag is secured to the lap belt and configured to inflate and deploy upward from the lap belt to a deployed position in front of the occupant. The system is configured to adjust the deployed position of the airbag in response to the position of the occupant.

The invention describes a vehicle occupant restraint system (2) comprising a control unit and at least two restraint elements (8, 10) for the protection of lower extremities (6, 6′, 7, 7′) in the area of a footwell (4) of a vehicle of a vehicle occupant seated in a particular vehicle seat of the vehicle, wherein a first restraint element (8) is configured as a knee airbag module (12), wherein a second restraint element (10) is provided for mounting into the footwell (4) of the vehicle, especially in an area of the footwell (4) of the vehicle arranged in the vehicle longitudinal direction (x) ahead of the knee airbag module (12), wherein, in a situation of restraint, the control unit can differentiate between different given situations, wherein the given situation can be determined via a vehicle seat position and parameters relating to vehicle occupants, wherein, in the situation of restraint, when a situation is given in which the vehicle seat (5) is in a position shifted backwards, especially in a position shifted backwards compared to the standard position, and the vehicle occupant is a short and/or light person, the control unit only activates the foot airbag module (16) of the second restraint element (10).

The invention relates to a marking object that can be placed on a vehicle child seat for adaptive actuation of an airbag, which is configured to reflect electromagnetic radiation and mark a position and/or orientation of the vehicle child seat in relation to a vehicle seat for an imaging sensor based on the reflection, in order to actuate the airbag depending on the position and/or orientation of the vehicle child seat, wherein the marking object is a Quick Response code, radar reflector, lidar reflector, or infrared reflector. The invention also relates to a vehicle child seat, a method for determining a position and/or orientation of a vehicle child seat in relation to a vehicle seat, and interior monitoring system, a computer program for adaptive actuation of an airbag and a computer readable data carrier.

A detector includes a first flexible sheet, a second flexible sheet placed opposite to the first flexible sheet, and an insulation sheet intervening between them. The first flexible sheet includes a second antenna unit and first contact portions formed on a first opposing surface. The second flexible sheet includes a detection unit and second contact portions formed on a second opposing surface. The first contact portions and the second contact portions become a state of contact by an external force based on the seating of an occupant, cause the second antenna unit to output a transmission signal to the detection unit, and cause the detection unit to output a detection signal to the second antenna unit.

An intelligent vehicle seat monitoring and alerting system, comprising: an enclosure, a camera being adapted to detect motion and to recognize faces in conjunction with suitable processing hardware and software, a distance detection sensor, adapted to measure a distance to a target object and to detect the presence of objects at different distance than an initially taught reference distance, for detecting the presence of an object in a target vehicle seat, by utilizing the camera and the distance detection sensor, a controller for controlling the camera and the TOF sensor, to alert a driver when detecting a child being left in a parking vehicle's seat, a communication module capable of communicating wirelessly with one or more remote stations, a rechargeable power storage of suitable capacity for providing sufficient electric power for the operation of the system, a charging port utilized as a power supply connection inlet being connected to a vehicular power supply, and a charging management module being adapted to control the charging of the rechargeable power storage through the charging port, and to detect a vehicle's engine shut-off resulting with the power supply to the charging port being shut-off.

The invention describes a vehicle occupant restraint system (2) comprising a control unit and at least two restraint elements (8, 10) for the protection of lower extremities (6, 6′, 7, 7′) in the area of a footwell (4) of a vehicle of a vehicle occupant seated in a particular vehicle seat of the vehicle, wherein a first restraint element (8) is configured as a knee airbag module (12), wherein a second restraint element (10) is provided for mounting into the footwell (4) of the vehicle, especially in an area of the footwell (4) of the vehicle arranged in the vehicle longitudinal direction (x) ahead of the knee airbag module (12), wherein, in a situation of restraint, the control unit can differentiate between different situations, wherein the control unit, in the situation of restraint, activates at least the first restraint element (8) and, depending on the given situation, additionally activates the second restraint element (10) and/or a partial element of the first restraint element (8) and/or a partial element of the second restraint element (10).

A method for automatically controlling an emotional environment in a vehicle is provided. The method includes generating reflected wave information by radiating an electromagnetic wave toward a rear seat of the vehicle and receiving a reflected wave. A degree of activity is determined based on the reflected wave information and at least one device installed within the vehicle is operated based on the degree of activity.

In various examples, systems and methods are disclosed that accurately identify driver and passenger in-cabin activities that may indicate a biomechanical distraction that prevents a driver from being fully engaged in driving a vehicle. In particular, image data representative of an image of an occupant of a vehicle may be applied to one or more deep neural networks (DNNs). Using the DNNs, data indicative of key point locations corresponding to the occupant may be computed, a shape and/or a volume corresponding to the occupant may be reconstructed, a position and size of the occupant may be estimated, hand gesture activities may be classified, and/or body postures or poses may be classified. These determinations may be used to determine operations or settings for the vehicle to increase not only the safety of the occupants, but also of surrounding motorists, bicyclists, and pedestrians.