A communication system for a motor vehicle having a plurality of seats includes a plurality of occupant sensors each detecting the presence of a passenger in a respective one of the seats. Passenger identification means identifies each of the passengers detected by the occupant sensors. A database stores medical information in association with each of the identified passengers. Detecting means detects that the motor vehicle has been in a crash. A transmitter wirelessly communicates with a remote emergency responder. An electronic processor responds to the detecting means detecting that the motor vehicle has been in a crash by causing the transmitter to transmit a signal to the remote emergency responder. The signal informs the remote emergency responder of the respective medical information and seat location associated with each passenger of the motor vehicle.

Examples of the disclosure relate to example devices and methods for generating a map of a vehicle’s passenger compartment and controlling features of the vehicle based on the map. An example vehicle with a passenger compartment mapping system includes one or more sensors to capture sensor data, which includes depth data for a passenger compartment of the vehicle. The system also includes one or more processors to generate a passenger compartment map from the sensor data, and control one or more subsystems of the vehicle based on the passenger compartment map.

A vehicle electronic control device includes a detection device configured to detect a state of an occupant, a first control device, and a second control device. The second control device is configured to refer to a database defining a relationship between the state of the occupant and a first time and to autonomously drive the vehicle at speeds equal to or lower than the maximum allowable speed from a switching time that is the time at which the first control device becomes unable to control the vehicle. The database is set in such a manner that the maximum allowable speed corresponding to a second state of the occupant is lower than the maximum allowable speed corresponding to a first state of the occupant when the first time corresponding to the second state is longer than the first time corresponding to the first state.

A method for controlling a safety device of a vehicle. The safety device reacts to an imminent collision by an intervention in a longitudinal and/or lateral guidance of the vehicle. The method includes reading in environment data and trip data regarding the collision object in an environment of the vehicle and the vehicle, and seat occupancy data regarding an occupancy state of at least one seat of the vehicle; ascertaining: an expected impingement side of the collision object on the vehicle; a velocity change of the vehicle in the context of the collision; and a seat occupancy distribution in the vehicle, using the seat occupancy data; executing an evaluation of the velocity change with regard to a threshold value and/or of the seat occupancy distribution relative to the expected impingement side; generating, depending on a result of the evaluation, a control signal for the safety device.

A motion sickness estimation device including processing circuitry configured to calculate a sensory conflict amount on a basis of a motion of an occupant's head caused by vibration of a vehicle; extract a feature of a traveling situation on a basis of at least one of the motion of the occupant's head or a motion of the vehicle; determine a habituation progress state, which is a state in which the occupant's habituation to the traveling situation has progressed, on a basis of biometric information of the occupant; set sensitivity to the feature of the traveling situation on a basis of the habituation progress state; correct the sensory conflict amount on a basis of the sensitivity; and estimate a motion sickness state of the occupant on a basis of the sensory conflict amount that has been corrected.

Systems and methods can improve passenger safety for an Autonomous Vehicle (AV) based on the integration of sensor data captured by the AV's interior and exterior sensors. The AV can determine passenger occupancy data corresponding to where each passenger is detected within the AV by the interior sensors. The AV can determine multiple sets of one or more driving actions that the AV can perform at a future time. The AV can generate crash impact data corresponding to where each passenger is detected from one or more simulated collisions between the AV and one or more objected detected by the exterior sensors when the AV performs one or more sets of driving actions from among the multiple sets. The AV can determine ranked sets of driving actions based on the passenger occupancy data and the crash impact data.

A vehicle for transporting passengers include a floor board on which the passengers ride. The vehicle further includes a passenger distribution detection device that detects a passenger distribution that is a distribution of the passengers on the floor board. The vehicle further includes a control device that executes a passenger guidance control that guides the passengers on the floor board such that the passenger distribution approaches a target passenger distribution to increase a stability of the vehicle.

Various systems and methods are provided for determining a posture of an occupant of a vehicle. In one embodiment, a method comprises capturing images of an occupant in a vehicle via a vehicle camera, determining a current posture of the occupant and a recommended posture for the occupant based on the captured images and body measurements of the occupant, and outputting a guidance based on a difference between the current posture and the recommended posture. In this way, a comfort of the occupant may be increased by guiding the occupant toward a more ergonomic posture.

Apparatuses, systems and methods are provided for vehicle operator gesture recognition and transmission of related gesture data. More particularly, apparatuses, systems and methods are provided for vehicle operator gesture recognition and transmission of related gesture data to at least one geographic map programming interface.

An example operation includes one or more of monitoring, by a transport exterior a location, an exchange performed in an interior of the location by a recent occupant of the transport, and completing, by the transport, the exchange.