An ISS is a seating system that actively adjusts to improve an occupant's comfort, performance, and safety in a specific driving environment. The ISS determines the occupant's posture, position on the seat surface, and/or physiological state, for example, by applying a machine vision process. The ISS can further determine a driving environment. The ISS adjusts its settings and settings of the vehicle according to one or more factors such as an occupant's posture, the occupant's physiological state, the occupant's preferences, and/or the driving environment. The ISS can include a state machine that determines a current state and determines if a change has occurred such that the system should shift to another state that best suits this change. The ISS makes adjustment according to system settings associated with the best suitable state.

One variation of a method for renting a vehicle includes: receiving a signal from a fleet manager, the signal specifying a current availability of the vehicle for rent; updating a visual indicator arranged on the vehicle according to the signal, the visual indicator visually detectable from outside the vehicle; receiving identification information of a user proximal the vehicle; enabling access to the vehicle for the user in response to verification of the user as a driver of the vehicle; determining, through a sensor arranged within the vehicle, that the user is seated in a driver's seat within the vehicle; and enabling ignition of the vehicle for the user in response to determination that the user is seated in the driver's seat.

An in-vehicle terminal includes: a measurement unit that measures electric field strengths of radio waves for wireless communication emitted from information terminals located in a vicinity thereof; a main terminal identifying unit that identifies a predetermined main terminal among the information terminals; and a communication unit that establishes wireless communication with the identified main terminal and transmits a first electric field strength for another information terminal than the main terminal measured by the measurement unit, via the wireless communication to the main terminal.

A system for notifying emergency services of a vehicular crash may (i) receive sensor data of a vehicular crash from at least one mobile device associated with a user; (ii) generate a scenario model of the vehicular crash based upon the received sensor data; (iii) store the scenario model; and/or (iv) transmit a message to one or more emergency services based upon the scenario model. As a result, the speed and accuracy of deploying emergency services to the vehicular crash location is increased. The system may also utilize vehicle occupant positional data, and internal and external sensor data to detect potential imminent vehicle collisions, take corrective actions, automatically engage autonomous or semi-autonomous vehicle features, and/or generate virtual reconstructions of the vehicle collision.

Systems, devices, and techniques are provided for occupancy assessment of a vehicle. For one or more occupants of the vehicle, the occupancy assessment establishes position and/or identity for some or all of the occupant(s).

An in-seat experience system includes: a seat which includes a seat body, a sensor, and a seat controller allowed to acquire a measurement value from the sensor; an experience instruction device connected to the seat controller, configured to notify an occupant seated on the seat body a motion instruction and to store user identification information; and a server capable of communicating with the experience instruction device. The experience instruction device makes a determination based upon a measurement value of the sensor as to whether or not a first condition is satisfied, and to transmit a result of the determination to the server when at least the first condition is satisfied, and the server is allowed to increase a point score stored for the corresponding user identification information with a condition that the result of the determination that the first condition is satisfied is received from the experience instruction device.

Embodiments related to systems and methods for controlling an active vehicle seat are described. In some embodiments, the active vehicle seat is controlled based at least partly on internal sensor information, external sensor information, and operator input from a user interface.

A system for notifying emergency services of a vehicular crash may (i) receive sensor data of a vehicular crash from at least one mobile device associated with a user; (ii) generate a scenario model of the vehicular crash based upon the received sensor data; (iii) store the scenario model; and/or (iv) transmit a message to one or more emergency services based upon the scenario model. As a result, the speed and accuracy of deploying emergency services to the vehicular crash location is increased. The system may also utilize vehicle occupant positional data, and internal and external sensor data to detect potential imminent vehicle collisions, take corrective actions, automatically engage autonomous or semi-autonomous vehicle features, and/or generate virtual reconstructions of the vehicle collision.

A computer-implemented method is provided for predicting occupant location based on vehicular collision. The method includes receiving, at a computing system including one or more processors, information indicative of a vehicle crash involving a vehicle occupant. The method also includes receiving, at the computing system, information indicative of a position of the vehicle occupant within the vehicle prior to the vehicle crash. The method also includes determining, by the one or more processors, a probability of ejection of the vehicle occupant according to (i) the information indicative of the vehicle crash and (ii) the position of vehicle occupant. The method also includes providing, by the computing system, the probability of ejection of the vehicle occupant to one or more emergency responders.

In exemplary embodiments, methods and systems are provided for controlling airflow of a climate control system of a vehicle. In one embodiment, a system is provided that includes one or more sensors and a processor. The one or more sensors are configured to obtain sensor data pertaining to a climate control system of a vehicle. The processor is coupled to the one or more sensors, and is configured to at least facilitate dynamically adjusting control of airflow of the climate control system toward one or more locations inside a cabin of the vehicle, based on the sensor data.