A system for detecting a condition associated with an occupant in a vehicle. The system may include a plurality of sensors configured to acquire a first set of data indicative of occupancy of the vehicle and a second set of data indicative of at least one operating status of the vehicle, and at least one controller. The at least one controller may be configured to aggregate the first set of data and the second set of data, automatically determine the condition associated with the occupant in the vehicle based on the aggregated data, and generate a notification based on the condition.

A system includes a vehicle, the vehicle comprising a control system and a wireless transceiver operatively connected to the control system. The control system is configured to wirelessly communicate with a wearable device worn by a user using the wireless transceiver and the control system is configured to receive input from one or more sensors of the wearable device.

Embodiments include a vehicle comprising a user interface, a first sensor coupled to a child seat for detecting a child seat belt status; a gear selector for selecting a vehicle gear, and a processor communicatively coupled to the first sensor and the gear selector, and configured to cause the user interface to present a first notification if a first alarm condition is detected based on the child seat belt status and a selected gear. Embodiments also include a method of providing child seat monitoring in a vehicle, the method comprising receiving a gear position from a vehicle gear selector, receiving a child seat belt status from a first sensor coupled to a vehicle child seat, and presenting a first notification using a vehicle user interface if the gear position is a non-park position and the child seat belt status is unbuckled.

In one embodiment, one or more suspension systems of a vehicle may be used to mitigate motion sickness by limiting motion in one or more frequency ranges. In another embodiment, an active suspension may be integrated with an autonomous vehicle architecture. In yet another embodiment, the active suspension system of a vehicle may be used to induce motion in a vehicle. The vehicle may be used as a testbed for technical investigations and/or as a platform to enhance the enjoyment of video and/or audio by vehicle occupants. In some embodiments, the active suspensions system may be used to perform gestures as a means of communication with persons inside or outside the vehicle. In some embodiments, the active suspensions system may be used to generate haptic warnings to a vehicle operator or other persons in response to certain road situations.

Systems and methods for controlling movement of an active payload support system. In one example, a seat system for a vehicle includes a seat, a support structure coupled to the seat and including an actuator configured to move the seat at a command angle relative to a floor of the vehicle responsive to movement of the vehicle, at least one sensor positioned to detect movement of the vehicle, and a controller configured to receive a signal from the at least one sensor, generate a command signal to instruct the actuator to move the seat relative to a floor of the vehicle, determine whether the command signal will cause the seat to exceed a limit, scale the command signal to conform to movement of the vehicle within the limit, and provide a force command to the actuator to move the seat based on the scaled command signal.

A vehicle includes a smart key which periodically transmits identification information to an external device, a communication unit which receives information on a driver corresponding to the identification information generated by the smart key from the external device, and a control unit which displays information preset by the driver based on the information on the driver received from the communication unit or automatically controls devices in the vehicle pre-stored by the driver.

Provided is a child restraint system (CRS) with automated installation that provides automated feedback and control of seat installation angle, belt latching and tightening, and confirmation of correct install. The CRS utilizes sensors to monitor CRS base angle relative to level, confirm correct latching of the CRS to its base and then to the vehicle seat, and confirm tightening of the belts to the required tension to be crashworthy. The stepwise operation and confirmation of the installation procedure may be operated via button(s) or other tactical input, and relayed to the user via electronic visual display and/or audible means. All operations will be overseen and processed by an integrated control system, affording minimal user decision or interface. An intelligent latching device which can be adapted for use with an existing CRS is also provided.

An airbag system for a vehicle is provided that prevents a passenger seated in each seat from being struck and injured by a roof airbag when the roof airbag is deployed in the event of vehicle collision. In addition, the airbag system for a vehicle secures safety by effectively protecting the passenger using the roof airbag.

Embodiments include a vehicle comprising a user interface, a first sensor coupled to a child seat for detecting a child seat belt status; a gear selector for selecting a vehicle gear, and a processor communicatively coupled to the first sensor and the gear selector, and configured to cause the user interface to present a first notification if a first alarm condition is detected based on the child seat belt status and a selected gear. Embodiments also include a method of providing child seat monitoring in a vehicle, the method comprising receiving a gear position from a vehicle gear selector, receiving a child seat belt status from a first sensor coupled to a vehicle child seat, and presenting a first notification using a vehicle user interface if the gear position is a non-park position and the child seat belt status is unbuckled.

A vehicle seat includes a seat foundation coupled to a floor of a vehicle, a seat bottom coupled to the seat foundation to move back and forth along a longitudinal axis relative to the floor, and a seat back coupled to the seat bottom to extend upwardly away from the seat bottom. The seat back pivots about an axis relative to the seat bottom.