A system in facility includes a plurality of electric mobility vehicles, and a server which stores information of the electric mobility vehicles. In this system in facility, a user operates one of the electric mobility vehicles to move the electric mobility vehicle, after the user finishes using the electric mobility vehicle, the electric mobility vehicle moves to a standby area by automatic driving, and usage information of the electric mobility vehicle by the user is stored in a management data in a server, and at least one of a seating sensor for a seat unit and a occupancy sensor for a luggage carrier of the electric mobility vehicle is provided in each of the electric mobility vehicles.

A restraining device control system includes: a restraining device that is provided at a vehicle seat and that restrains an occupant seated in the vehicle seat; a surrounding environment detection unit that detects an environment surrounding a vehicle; and a control unit that increases a restraining force on the occupant by the restraining device in a case in which it has been predicted, from the surrounding environment of the vehicle, that vacillation of the vehicle while in an autonomous driving mode will exceed a threshold amount and that decreases the restraining force on the occupant by the restraining device in a case in which it has been predicted, from the surrounding environment of the vehicle, that the vehicle will maintain a state in which vacillation of the vehicle while in the autonomous driving mode is less than the threshold amount.

Methods, systems and apparatuses may provide for technology that conducts an automated vision analysis of image data associated with an interior of a vehicle cabin, determines a state of a child restraint system (CRS) based on the automated vision analysis, and generates an alert if the state of the CRS does not satisfy one or more safety constraints. In one example, the technology identifies the safety constraint(s) based on a geographic location of the vehicle cabin.

A method for a seat belt system (10) in a vehicle (14), the seat belt system (10) comprising a control unit (36) and at least one seat belt (18) with an extendable webbing (20) and a webbing extension measuring device (30), includes the steps of: a) determining whether a vehicle seat (16) is occupied, b) determining whether the webbing (20) is in a storage position, if the vehicle seat (16) is not occupied, and c) outputting a warning signal, in particular via an output device (34), if the webbing (20) is not in the storage position.

Moreover, the invention provides a seat belt system (10) for a vehicle (14) comprising an extendable seat belt (17, 18) as well as a vehicle (14) comprising a seat belt system (10).

The techniques of this disclosure relate to a vehicle occupancy-monitoring system. The system includes a controller circuit that receives occupant data from an occupancy-monitoring sensor of a vehicle. The controller circuit determines an occupancy status of respective seats in a cabin of the vehicle based on the occupancy-monitoring sensor. The controller circuit indicates the occupancy status of the respective seats on a display located in a field of view of occupants of the vehicle. The display is integral to one of a roof light module, a door panel, or a headliner of the cabin. The system can improve passenger safety by alerting the operator and other occupants about the occupancy status of the passengers.

A computer implemented method for detecting whether a seat belt is used in a vehicle comprises the following steps carried out by computer hardware components: acquiring an image of an interior of the vehicle; determining a plurality of sub-images based on the image; detecting, for at least one of the sub-images, whether a portion of the seat belt is present in the respective sub-image; and determining whether the seat belt is used based on the detecting.

A motor vehicle (1) has a driver’s seat (8) which is assigned a safety belt (20) for a driver. The safety belt (20) here is held on a pivotable bracket (13). This bracket (13) is pivotable between a releasing position, which permits entry, and a restraining position, which protects the driver. The bracket (13) here is disposed in such a manner that said bracket (13) in the releasing position holds the safety belt (20) in a position in which the latter impedes the driver. In order to avoid any impediment of the driver in the restraining position of the bracket (13), the bracket (13) above the driver’s seat is elbowed away from the latter. (FIG. 3)

A wheelchair securing structure includes: a securing device provided in a wheelchair securing space inside a vehicle cabin, the securing device being configured to secure a wheelchair; a securing detection portion configured to detect that the wheelchair is secured by the securing device; and a display portion provided at a position where the display portion is visually recognizable by an occupant of the wheelchair from the wheelchair securing space inside the vehicle cabin, the display portion being configured to display a secured state of the wheelchair, the secured state being detected by the securing detection portion.

A system for detecting improper usage of a seatbelt of a vehicle includes a vehicle seat having a seat cushion and a seat back. A shoulder belt and a lap belt are intended to restrain an occupant sitting on the vehicle seat. The system includes a sensor module associated with the shoulder belt and the lap belt. The sensor module generates signals indicative of at least one parameter associated with the vehicle seat, the shoulder belt, and the lap belt when the occupant is sitting on the vehicle seat. The system also includes a controller that receives the signals indicative of the at least one parameter associated with the seat back, the shoulder belt, and the lap belt. The controller analyzes the received one or more signals, and determines whether the seatbelt is being used improperly by the occupant, based on the analysis.

Guidance to a vehicle occupant is directed to manual adjustment of a height of a D-ring mechanism of a safety belt. First data of the occupant is collected which is indicative of a target height for the D-ring mechanism. Second data is collected indicative of a current height of the D-ring mechanism. The target height and the current height are compared to generate an adjustment amount whenever their difference is greater than a predetermined threshold. Visual guidance is presented to the occupant on an HMI display panel wherein the visual guidance describes taking an particular action to achieve the manual height adjustment of the D-ring mechanism. A further visual instruction is presented to the occupant on the HMI display panel wherein the visual instruction identifies the adjustment amount.