The present invention relates to a measurement arrangement for detecting an occupancy of a motor vehicle seat arrangement with at least one seat, which comprises a sensor arrangement with at least one sensor (10) for detecting a deformation of a lower side (21) facing away from the seating surface or of a force loading by a lower side (21) facing away from the seating surface of a seat cushion (20) of at least one seat of the motor vehicle seat arrangement, which is fastened on a structural element (40) of the motor vehicle.

A vehicle seat includes a seat bottom coupled to a floor of a vehicle to move relative to the floor and a seat back coupled to the seat bottom to move relative to the seat bottom.

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.

An occupant detection method includes detecting a load applied to a seat for a vehicle, determining whether or not an occupant is seated at the seat, calculating a load deviation value indicating deviation of the load, determining whether or not the deviation exists at the seat on the basis of the load deviation value, and estimating that a seating posture of the occupant is inclined in a direction in which the load is deviated in a case where it is determined that the deviation exists and that a stable state is established, the stable state corresponding to a state in which a difference between a first change amount in a first cycle and a second change amount in a second cycle is within a predetermined range.

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 occupant detection method includes detecting a load applied to a seat for a vehicle, detecting that an occupant is seated at the seat, holding a local maximum of the load which is detected when the occupant becomes seated, setting a standard value of the load in a state in which the occupant is seated at the seat, and estimating a body height of the occupant on the basis of a comparison between the local maximum of the load and the standard value of the load, wherein when the body height of the occupant is estimated, the larger a difference between the local maximum of the load and the standard value of the load is, the higher body height of the occupant is estimated.

Example embodiments presented herein are directed towards a seat assembly, and corresponding method and computer readable medium, for adjusting a seat in an autonomous vehicle. The adjustment is provided such that a seat occupant may control the adjustment may providing a natural pushing force once the vehicle is in an autonomous driving mode.

Load sensors are disposed on four corners of a seat cushion. An occupant decision section of an occupant detection ECU decides a type of an occupant on a vehicle seat based on loads detected by the load sensors. A CRS changing section that prohibits the occupant decision section from changing a decision to a decision result that an adult is seated in the vehicle seat and changes the decision to a decision result that a child seat is attached on the vehicle seat when an engagement of a tongue plate with a buckle of a seat belt device is detected by a buckle switch and a buckle load calculated by buckle load calculation section is less than a predetermined buckling load threshold in a case where the occupant decision section decides that an adult is seated in the vehicle seat.

A control system is disclosed for enhancing the visibility of a driver of a vehicle. The control system may include a sensor configured to generate a signal indicative of a weight placed on a passenger seat and at least one motor configured to adjust a position of the passenger seat. The control system may also include a controller in communication with the sensor and the at least one motor. The controller may be configured to receive the signal from the sensor, determine that the passenger seat is unoccupied based on the signal, and automatically generate a command signal directed to the at least one motor to adjust the passenger seat to a prospective position.

A vehicle seat with an embedded occupancy detector system and manufacturing method for same, and an occupant protection system including an occupancy detector system embedded in a vehicle seat as described herein. Examples include a molded vehicle seat with one or more inserts including an occupant detection system with one or more sensor pads. A gap housing one or more sensor pads of an occupant detection system may be provided between a surface of an insert and a recessed surface of the molded vehicle seat.