A wire harness connected to a sensor is positioned on a back surface of a pad of a vehicle seat supported by a panel. The vehicle seat includes a panel; a pad supported by the panel; a skin material covering a front surface of the pad; and a sensor provided between the front surface of the pad and the skin material for acquiring information on a seat occupant, wherein the pad is provided with a through hole passed from the front surface of the pad to a back surface of the pad, and a recess formed in the back surface of the pad and connected to the through hole, the wire harness connected to the sensor extending in the through hole and the recess.

Electronic devices and methods are provided in which a pressure applied, by a driver, to a seat of a moving object driven by the driver is sensed. A state of the driver is determined based on frequency characteristics with respect to a change in the pressure sensed by the sensor.

A vehicle seating system includes a vehicle seat, piezoelectric sensors individually positioned at respective locations within the seat corresponding to anatomical locations of a person sitting in the seat, and a controller. The sensors to generate electrical signals in response to mechanical stress applied on the sensors from biologically motivated force inputs of the person. The controller to detect from the electrical signals generated by the sensors biometric information of the person corresponding to the biologically motivated force inputs of the person.

An occupant support adapted for use in a vehicle includes a seat bottom, a seat back, and a sensory system. The seat bottom is coupled to a floor of the vehicle. The seat back extends upwardly away from the seat bottom. The sensor system is configured to monitor for fatigue of an occupant of the occupant support.

Disclosed are active vehicle seat assemblies, methods for making and using such seat assemblies, and vehicles with active seat assemblies for counteracting unwanted inertial forces. An active vehicle seat assembly is disclosed that includes an occupant chair with interconnected seat and backrest portions. A motion sensor detects motion of the occupant chair and outputs signals indicative thereof. An automated platform movably mounts the occupant chair to the vehicle body. The platform includes: a pitch plate that pivots about two lateral axes; a pitch actuator that selectively pivots the pitch plate; a roll plate that pivots about two longitudinal axes; and a roll actuator that selectively pivots the roll plate. An on-board controller responds to signals from the motion sensor indicative of inertial motion disturbances to the chair by transmitting control signals to the pitch and/or roll actuators to pivot the pitch and/or roll plates to thereby counteract the inertial disturbances.

A vehicle passenger detection apparatus is configured to monitor an occurrence of a passenger entering into a vehicle from a vacant seat state or an occurrence of the vacant seat state due to the passenger exiting from the vehicle, and to determine by calculations whether a detection value of a load sensor is stable before the passenger entered the vehicle or after the passenger exited the vehicle. Updating of a passenger determination result is executed even in a state in which a determination result from a vibration change amount judgment section indicates a disturbance has occurred, when the vehicle entry and exit determination section determines that the detection value of the load sensor is stable before the passenger entered the vehicle or after the passenger exited the vehicle.

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.

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.

An occupant support adapted for use in a vehicle includes a sensory system and a control system. The sensor system is configured to generate signals indicative of at least one of a physiological characteristic of the occupant.

A piezoelectric sensor includes: a piezoelectric element which is long and which includes a first electrode, a second electrode, and a piezoelectric body interposed between the first and second electrodes; and a laminate film which is long and which surrounds the piezoelectric element. The laminate film includes a wide portion whose length along a shorter side direction of the laminate film is not less than twice a length of the piezoelectric element which length is along a shorter side direction of the piezoelectric element.