Vehicle seat adjustment systems that move more than one seat in a linked manner are disclosed. A vehicle seat adjustment system for a vehicle includes a front seat of the vehicle, one or more passenger seats behind the front seat, an input device configured to receive an input for adjusting positions of the front seat, a first actuator configured to adjust positions of the front seat, a second actuator configured to adjust positions of the one or more passenger seats, and a controller communicatively coupled to the input device and the first and second actuators. The controller instructs the first actuator to move the front seat in a longitudinal direction for a first distance in response to the received input, and instructs the second actuator to move the one or more passenger seats in the longitudinal direction for a second distance in response to the received input.

A vehicle seat includes a seat cushion that includes a seat cushion frame, a riser that supports the seat cushion frame, a seat position adjusting device that moves and adjusts the seat cushion back and forth, and a load detector that detects a load applied to the seat cushion. The riser includes a bottom wall and a sidewall that extends upward from an end portion of the bottom wall. The seat position adjusting device includes an upper rail that supports the riser and slides a lower rail. The load detector is positioned between the upper rail and the bottom wall. The upper rail, the load detector, the bottom wall, and the bracket are co-clamped with a first fastening member, and the bracket is secured to the sidewall with a second fastening member.

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.

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.

An occupant or object sensing system in a vehicle includes electrical circuits for resistive and/or capacitive sensing and corresponding circuits shielding the sensing system from interference. A sensing circuit and a shielding circuit may be printed by screen printing with conductive ink on opposite sides of a non-conductive substrate. The substrate is a plastic film or other fabric that has an elastic memory structure that is resilient to stretching. The conductive inks used to print circuits onto the substrate have a similar resilience to stretching such that the substrate and the circuits thereon can be subject to deforming forces without breaking the printed circuits. The substrate may be covered with a carbon polymer layer to provide alternative conductive paths that enable fast recovery for conduction in the presence of any break in the printed conductive traces on the substrate.

An occupant discrimination system of a vehicle seat includes a load detecting portion disposed on a lower side of a seat and detecting a load acting on the seat; an occupant discrimination portion discriminating a state of an occupant among a no occupant state, adult seated state, and child seat fixed states based at least on a load detected from the load detecting portion and a load continuation duration.

Vehicle seat adjustment systems including cameras are disclosed. The vehicle seat adjustment system includes a camera configured to capture a seat arrangement of a front seat of a vehicle and one or more seats behind the front seat, a screen, communicatively coupled to the camera, configured to display the seat arrangement captured by the camera, an input device configured to receive an input from a user for adjusting positions of the one or more seats, an actuator communicatively coupled to the input device and configured to adjust positions of the one or more seats, and a controller communicatively coupled to the camera, the screen, the input device and the actuator. The controller receives the input from the input device and instruct the actuator to adjust the positions of the one or more seats based on the input from the user.

A vehicle seat includes a pair of side frames and a load sensor. The load sensor is provided at a lower portion of the side frame or below the side frame. The vehicle seat further includes a supporting member which is connected to the side frame and which supports a seated person. The supporting member includes a seat portion which receives a weight of a seated person. The seat portion is provided below the load sensor.

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 vehicle control system includes variable maneuvering limits based at least in part on whether the vehicle is carrying cargo (i.e., passengers or other cargo). The system can include a cargo classification system comprising one or more internal sensors, an imager, and an image interpreter. The cargo classification system can determine if the vehicle is carrying cargo and classify the cargo (e.g., passengers or other cargo). Based at least in part on this classification, the vehicle control system can set various vehicle maneuvering limits. When the vehicle is empty, the vehicle control system can maneuver the vehicle at, or near, the actual maneuvering limits for the vehicle (e.g., maximum longitudinal acceleration, braking and lateral acceleration that can be generated by the vehicle). When the vehicle is carrying cargo, the vehicle control system can maneuver the vehicle at a lower threshold to prevent passenger discomfort and/or cargo damage or discomfort.