An in-vehicle computer is programmed to determine that a driver's hands are at least one predetermined location in the vehicle, the at least one predetermine location including a location on a steering wheel, determine that a vehicle passenger is in a safe position with respect to a human-machine interface; and provide passenger access to the human-machine interface such that the passenger may access operations of the computer that are inaccessible to the driver.

A wheel adjustment system for an agricultural implement includes a controller having a processor and a memory. The processor is configured to receive a first signal indicative of a ground speed of the agricultural implement, receive a second signal indicative of a desired position of a wheel of the agricultural implement, receive a third signal indicative of a current position of the wheel of the agricultural implement, and output a control signal to adjust a position of the wheel of the agricultural implement based on the first signal, the second signal, and the third signal, wherein a rate of adjustment of the position of the wheel varies based on the first signal.

A safety alert system for a specific vehicle includes an Internet-connected server executing software, a digital data repository, a profile associated with the specific vehicle and identifying the specific vehicle and comprising contact information for a person, a computerized monitoring apparatus located in the specific vehicle with a two-way Internet connection to the Internet-connected server, global positioning system (GPS) circuitry coupled, a plurality of sensors, sensing both environmental conditions and status of apparatus of the specific vehicle, and reporting to the monitoring apparatus, and at least one set of variable values stored in the digital data repository indicating an alert status. The server keeps a log of reported variable values for the specific vehicle, periodically compares the variable values reported with the at least one set of variable values indicating an alert status, and issues an alert accordingly.

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 seat comprising a backrest; a seating portion connected to the backrest; and at least one measurement area defined on the backrest and/or on the seating portion, the at least one measurement area comprising at least one interdigital capacitive sensor capable of measuring a distance or a movement of a user occupying the seat.

Various systems and methods for providing an occupant profiling system are described herein. A system for profiling a vehicle occupant includes a vehicle control system, comprising: a sensor fusion circuit coupled to a plurality of sensors installed a vehicle seat, the sensor fusion circuit to: determine that a human occupant is seated in the vehicle seat; sample a backrest sensor arrangement and a base cushion sensor arrangement of the vehicle seat to obtain backrest sensor data and base cushion sensor data, when the human occupant is determined to be seated in the vehicle seat; sample, when the human occupant is determined to be seated in the vehicle seat, a height sensor to obtain a height sensor value; and statistically determine from the backrest sensor data, the base cushion sensor data, and the high sensor data, whether the human occupant matches a reference profile.

A method of integrating a device in upholstery of a foam seat element, including the steps of: placing the device in a plastic bag or surrounding it with a plastic film; placing the assembly in an injection mold; and injecting foam to form the seat element in one piece.

A passenger restraint device for amusement rides and a method for retaining at least one passenger by means of the restraint device. The device comprises at least one restraint element provided with at least one contact surface intended to be placed in contact with at least one part of the body of a passenger. The restraint element is movable between at least one open position, in which the restraint element is not in contact with the passenger and at least one closed position in which the restraint element is in contact with at least one part of the passenger's body. The restraint element comprises at least one sensor to detect a contact between the restraint element and at least one part of the body of the passenger, preferably a contact with a passenger's thighs.

A process is provided that uses a sensor system incorporated into the passenger cabin of a vehicle to detect children and/or pets left unattended and who are therefore at risk of serious injury or death due to heat stroke. If an unattended child or pet is detected, a variety of alerts are issued over time, the escalating nature of the alerts intended to insure a rapid response. After the system has operated long enough to insure that no child or pet has been left behind, the sensor system is automatically placed into a standby mode. In standby mode the sensor system may either be turned completely off in order to minimize off-line power consumption or it may be incorporated into an on-board security system.

A new approach is proposed that contemplates system and method to backseat child safety in a passenger vehicle by preventing locking of the vehicle in a parked state when at least one of its backseats is occupied. Specifically, one or more backseat sensors are each configured to detect if one of the backseats of the vehicle is occupied by a passenger. Upon accepting signals from the backseat sensors indicating that at least one of the backseat is occupied, a vehicle controller is configured to disallow locking of the vehicle in the parked state. The vehicle controller is configured to only enable locking of the vehicle when a backdoor corresponding to the occupied backseat has been opened as detected by one of a plurality of backdoor sensors, which generates and provides a backdoor signal to the vehicle controller when the corresponding backdoor to the occupied backseat is opened.