The present disclosure relates to a seat operation range setting system. The seat operation range setting system includes a lower rail disposed on a frame mounted to a floor panel of a chassis, an upper rail installed so as to be slidable along the lower rail, a contactless sensor connected to the upper rail, the contactless sensor being configured to sense a bracket disposed at one side of the lower rail, and a controller configured to receive an ON/OFF signal of the contactless sensor and to set a virtual limit of a seat.

In various example embodiments, devices, systems, and methods for a waist measuring belt are provided. An example waist measuring belt is made up of a belt buckle frame with attachments for a belt strap. The belt further includes a position measuring module coupled to the belt buckle frame that measures an attachment position of a second end of the belt strap to the belt buckle frame. The belt also includes a tension measuring module coupled to the belt buckle frame that measures a tension through the belt buckle frame and the belt strap. A memory and a wireless communication module attached to the belt may be used to store measurements and communicate with a mobile device or server. In various embodiments, estimated user waist sizes over time using measured values and belt-specific data may be used to estimate a user's waist size and generate a waist size history.

In various example embodiments, devices, systems, and methods for a waist measuring belt are provided. An example waist measuring belt is made up of a belt buckle frame with attachments for a belt strap. The belt further includes a position measuring module coupled to the belt buckle frame that measures an attachment position of a second end of the belt strap to the belt buckle frame. The belt also includes a tension measuring module coupled to the belt buckle frame that measures a tension through the belt buckle frame and the belt strap. A memory and a wireless communication module attached to the belt may be used to store measurements and communicate with a mobile device or server. In various embodiments, estimated user waist sizes over time using measured values and belt-specific data may be used to estimate a user's waist size and generate a waist size history.

A seat assembly with an adjustable head restraint assembly capable of being adjusted based on an approximate stature or spatial location of an occupant in the seat assembly. A seat assembly may include a sensor in the seat to detect if an occupant is present. The sensor may include a plurality of bladders and pressure sensors, a radar system, or a neuro-monitoring sensor. The sensor may send a signal to a controller indicating the presence of an occupant. The controller may approximate the size and/or spatial location of the occupant and send an adjustment signal to the head restraint adjustment mechanism to adjust the head restraint assembly to an in-use position. The controller may determine that an occupant is not present and send an adjustment signal to the head restraint adjustment mechanism to adjust the head restraint assembly to a non-use position.

The present disclosure generally relates to techniques for displaying composited user interfaces and/or customized user interfaces, such as based on contextual information and/or detecting the presence of electronic devices.

A vehicle control method is disclosed which is a method for adjusting a seat inside a vehicle. The vehicle control method includes: monitoring the surroundings of a passenger sitting in the seat through a camera installed inside the vehicle; sensing an object around the passenger through the monitoring; sending information on the sensed object to a server; receiving a preset seat setting value corresponding to the object information from the server; and adjusting the position of the seat according to the seat setting value. One or more of an autonomous vehicle according to the present invention, a user terminal, and a server may be associated with artificial intelligence, a robot, augmented reality (AR), virtual reality (VR), etc.

The present invention relates in general to the adjustment of vehicle seat and steering wheel positions, and in particular relates to an apparatus and method for automatic adjustment of driver sitting posture. The method for automatic adjustment of driver sitting posture according to the present invention comprises the following steps: determining an ergonomic parameter corresponding to a user; calculating a seat position parameter according to the ergonomic parameter; adjusting a seat position according to the seat position parameter; calculating a steering wheel position parameter according to the ergonomic parameter; and adjusting a steering wheel position according to the steering wheel position parameter.

A method for adjusting a seat in a vehicle includes adjusting the seat from an initial position to a passenger adjusted position based on receiving an input from a passenger. The method further includes determining the passenger exited the vehicle after adjusting the seat and predicting a likelihood of the passenger returning to the vehicle based on determining the passenger exited the vehicle. The method also includes adjusting the seat to the initial position based on the likelihood of the passenger returning is less than a passenger returning threshold. The method still further includes identifying a person approaching the vehicle after the passenger exited the vehicle based on information captured by one or more sensors of the vehicle. The method also includes adjusting the seat to a position associated with the previous passenger based on identifying the person approaching the vehicle as the previous passenger.

A system and method are provided for controlling an interior configuration of a vehicle. The system may include an interior vehicle component, an actuator component configured to adjust a physical configuration of the interior vehicle component, a vehicle operation controller configured to generate vehicle operation data representing the operation of the vehicle, and one or more processors configured to receive vehicle operation data and detect, by processing the vehicle operation data, a specific action taken by the vehicle. When the one or more processors detect a specific action taken by the vehicle, the one or more processors may cause the actuator component to adjust the interior vehicle component from a first physical configuration to a second physical configuration.

A car seat system for automatically displacing the movable components of the car seat. The car seat including sensors and a computing module to detect the measurements of a child placed in the car seat. The car seat system determines the current position of the movable components and displaces the movable components automatically based on the child's measurements or a desired amount. The car seat system automatically learns child's behaviors when the child is placed in the car seat. The car seat system learns schedules utilized by the child, routes taken by the driver of the car, and other data over a period of time. The behavioral, scheduling, routing, and other data obtained is stored by the car seat system and utilized to enhance the safety and comfortability of the child during a car ride. The car seat system also determines thickness of clothing worn by the child while placed in the car seat and adjusts the shoulder belts to accommodate for the clothing while providing a snug fit of the shoulder belts that fall within safety recommendations. The car seat also auto reclines to a desired angle and also rotates about itself to face the door. The car seat system includes an auto-incident detection mode. In this mode, the system detects an incident, such as an accident, hard braking, or another hazard, and automatically displaces the features in the car seat to make the car seat secure during the crash minimizing the effect of the incident on the child. The car seat also includes pretensioners and motors to release, pull back, and lock the car seat belts.