An embodiment related to a system, wherein the system comprising an alertness detector unit configured to detect an alertness signal of an occupant an alertness determination unit configured to determine an alertness of the occupant based on the alertness signal, an environment sensing unit configured to sense external data in a route, an analysis unit configured to analyze the external data to determine an external condition, a risk assessment unit configured to determine a risk level in real-time based on an analysis of the external data and the alertness of the occupant, and a control unit configured to adjust a seat if determined that the real-time risk level was above a threshold.

A method, system, and process are described to decrease muscle fatigue and improve circulation of an individual resting on a support device, such as an adjustable chair or bed. The body pose and heat distribution of the individual are determined and used to estimate muscle fatigue and circulation. The estimated muscle fatigue and circulation are then used to determine settings for the support device or the temperature of the environment.

A vehicle occupant information acquisition device includes a microcomputer, an acquisition unit and an alert unit. The microcomputer controls the vehicle to switch between an autonomous driving mode and a manual driving mode. The acquisition unit acquires, from vehicle occupants riding in the vehicle, information relating to driving suitability of the vehicle occupants. In a case in which the microcomputer is switching the vehicle from the autonomous driving mode to the manual driving mode, the microcomputer causes the alert unit to alert one of the vehicle occupants who is determined to be suitable to drive the vehicle based on the information acquired by the acquisition unit that he/she has been selected as the driver of the vehicle.

Described herein is a system for setting a component of a vehicle for a driver or passenger, such as a vehicle seat or mirror, to increase driver and/or passenger safety. The system includes a vehicle component having at least one user-adjustable setting, such as a recline angle for a seat back. The system also includes a sensor, such as a camera or force sensor, configured to detect body measurement data corresponding to a physical attribute of a user. For example, the body measurement data may include a height, a weight or the like. The system also includes an electronic control unit (ECU) coupled to the vehicle component and the sensor. The ECU is designed to determine an optimal setting for the vehicle component based on the body measurement data. The ECU can also control the vehicle component to have the optimal setting.

Embodiments include a vehicle comprising a seat, a first sensor coupled to the seat for detecting a seat angle, and a processor communicatively coupled to the first sensor and the seat, and configured to output a control signal for correcting the seat angle if the seat angle is not within a predetermined range of values. Embodiments also include a method of correcting a position of a vehicle seat having an occupant seated therein. The method comprises receiving, at a processor, an output detected by a sensor unit coupled to the seat; comparing, using the processor, the output to a predetermined threshold to determine whether an alarm condition exists; if it does, outputting a control signal for correcting the seat position, wherein the sensor unit includes an angular position sensor.

Method for controlling a vehicle including a smartphone-engaging coupling element. Data about operational status of the vehicle is transferred from one or more vehicle-resident systems to a smartphone when the smartphone is engaged with the coupling element. Commands are received by the vehicle from the smartphone when the smartphone is engaged with the coupling element, which commands being based in part on data previously transferred from the vehicle-resident system(s) to the smartphone when the smartphone is engaged with the coupling element. A vehicular system, e.g., seat positioning system, mirror positioning system, passenger compartment temperature control system, route guidance or navigation system, changes its operation in accordance with the commands received by the vehicle from the smartphone when the smartphone is engaged with the coupling element.

Embodiments of the present invention provide a method and system for enacting various driving profiles based on identifying the age and gender of the user. Initially, identifying information is acquired from a user of a vehicle. An identification program determines whether the driver is known, by comparing the identifying information to a set of stored identifying information. If the driver of the vehicle is known, as the identifying information from the user is similar to stored identifying information, then a specific driver profile associated with the specific driver is activated. If the driver is not known, as the identifying information from the user of the vehicle is not similar to the stored identifying information, then the age and gender of the user of the vehicle is determined. Based on the determined age and gender of the driver of the vehicle, various vehicle setting ranges are enacted.

Embodiments of the present invention provide a method and system for enacting various driving profiles based on identifying the age and gender of the user. Initially, identifying information is acquired from a user of a vehicle. An identification program determines whether the driver is known, by comparing the identifying information to a set of stored identifying information. If the driver of the vehicle is known, as the identifying information from the user is similar to stored identifying information, then a specific driver profile associated with the specific driver is activated. If the driver is not known, as the identifying information from the user of the vehicle is not similar to the stored identifying information, then the age and gender of the user of the vehicle is determined. Based on the determined age and gender of the driver of the vehicle, various vehicle setting ranges are enacted.

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.

Various systems and methods are presented regarding controlling respective positions of a seat back and seat base to mitigate the risk of a vehicle occupant submarining in the event of the vehicle being involved in a collision/rapid deceleration. Positioning of the seat back/seat base can be controlled in accordance with the occupant's physiology and posture, e.g., reclining. Cameras/radar sensors in the passenger compartment in conjunction with seat sensors can be generate physiology/positioning data, which can be processed, and based thereon, the seat back/base positions can be controlled by one or more motors.