Systems, apparatus and methods implemented in algorithms, hardware, software, firmware, logic, or circuitry may be configured to process data and sensory input to determine whether an object external to an autonomous vehicle (e.g., another vehicle, a pedestrian, road debris, a bicyclist, etc.) may be a potential collision threat to the autonomous vehicle. The autonomous vehicle may be configured to implement interior active safety systems to protect passengers of the autonomous vehicle during a collision with an object or during evasive maneuvers by the autonomous vehicle, for example. The interior active safety systems may be configured to provide passengers with notice of an impending collision and/or emergency maneuvers by the vehicle by tensioning seat belts prior to executing an evasive maneuver and/or prior to a predicted point of collision.

A device which detects a child presence in a car seat and communicates an audible and mobile-device reminder to the driver that a child occupant is in the seat is disclosed. The system utilizes internal sensors to monitor various vehicle occupancy conditions to determine when a triggering event has occurred while the car seat occupancy sensor is engaged. Once triggered, the system will immediately notify the driver that the child remains in the car seat inside the vehicle, and will also sent follow-up alerts.

A deformation detecting device includes weft yarns and warp yarns woven together. At least some of the weft yarns, or some weft yarns, and some warp yarns, are electrically conductive. The weft yarns include a flocking made up of non-electrically conductive fibers protruding substantially radially from the weft yarns. The electrically conductive yarns are connected to conductive ends for applying an electrical voltage, such that yarns that are connected to conductive ends with different polarities define respective plates of a capacitive sensor, while the fibers of the flocking of the weft yarns define a dielectric material interposed between the capacitive sensor plates. The device comprises an electronic control and processing unit configured to detect a deformation of the fabric based on a capacitance variation of the capacitive sensor.

Provided is a seat in which a physical quantity can be controlled according to a physique of an occupant. One aspect of the present disclosure provides a seat including a seat body that supports a body of an occupant, at least one driving device that changes a physical quantity of the seat body, and a controller that controls the at least one driving device. The controller includes a model generator that generates a human body model of the occupant, an analyzer that analyzes a state quantity of the human body model, and an instructing device that drives the at least one driving device based on a result of an analysis by the analyzer.

A vehicle seat sensor unit includes a seat occupancy sensor configured for wirelessly communicating with a control unit, at least one first seat detection sensor member and at least one second seat detection sensor member. The first seat detection sensor member is arrangeable in one out of a lower vehicle seat portion of a vehicle seat that is mountable in a vehicle in a removable manner, and a vehicle cabin floor, and the second seat detection sensor member is attachable to the other one of the lower vehicle seat portion and the vehicle cabin floor. The first seat detection sensor member and the second seat detection sensor member are configured to physically interact if mutually arranged within a specific distance. The physical interaction results in a detectable change of a status of at least one out of the first seat detection sensor member and the second seat detection sensor member.

A vital information measurement device and a vehicle seat which improves the durability of sheet-shaped sensors configured to detect vital information of a seated passenger can stably measure the heart rate of the seated passenger. A vehicle seat includes sheet-shaped sensors attached to a seat back, and can measure the heart rate of a seated passenger based on vital signals of the seated passenger detected by the sheet-shaped sensors. At each sheet-shaped sensor, a sensor overlap reduction section is provided to reduce partial overlapping of the sheet-shaped sensor when the seated passenger leans on the seat back. Specifically, each sheet-shaped sensor includes a first cutout extending toward the center of the sheet-shaped sensor at an outer peripheral portion of the sheet-shaped sensor, and a second cutout formed continuously from the first cutout and extending opposite to the center along the outer peripheral portion of the sheet-shaped sensor.

A seating posture is stabilized for the shoulders of a passenger seated on a vehicle seat. A vehicle seat is provided with a seat back configured to support the seated person from the rear. A shoulder support portion of the seat back configured to support a corresponding one of the shoulders of the seated passenger includes an air cell configured to expand when air is supplied. When the air cell expands, one end portion of the shoulder support portion on the outside in the width direction of the vehicle seat moves more forward than the other end portion of the shoulder support portion on the inside in the width direction.

The present disclosure relates to a method for determining the occupancy status of a seat of a motor vehicle, the method being implemented by a determination system comprising a seat, six interdigitated capacitive sensors, and a controller comprising a reference capacitance value and a threshold value for each interdigitated capacitive sensor, the method comprising a step of measuring three capacitance values for each interdigitated capacitive sensor, the following steps being implemented by the controller for the measured capacitance values: calculating a resulting capacitance value based on the measured capacitance values, calculating the difference between the resulting capacitance value and the reference capacitance value, comparing the calculated difference to the threshold value, determining the occupancy status of the seat, based on the result of the comparison.

A heat flux sensor is installed in such a way that heat flux emanating from a biological object present at a predetermined position is detectable. It is determined whether or not a biological object is present at the predetermined position by comparing sensing results of the heat flux sensor with determination criteria. The determination criteria is preset according to heat flux that can be sensed when a biological object is present at the predetermined position. When the sensing results of the heat flux sensor satisfy the determination criteria, in other words, when the heat flux sensed by the heat flux sensor is the heat flux emanating from a biological object, it is determined that a biological object is present at the predetermined position. Consequently, it is possible to realize accurate detection of a biological object.

A seat assembly is provided herein. The seat assembly includes a seat member having a support surface. A pair of seat member bolsters is disposed on opposing sides of the seat member. A seat base supports the seat member and has a wraparound sidewall that extends above a bottom portion of each seat member bolster.