A system includes an electro-dermal potential sensing system to sense electro-dermal potential of a person and configured to output an electro-dermal potential signal, as well as at least one physiological sensor to measure at least one physiological state and output at least one physiological signal. The system also includes a controller to receive the electro-dermal potential signal from the electro-dermal potential sensing system and the at least one physiological signal to determine a drowsiness state of the person.

Method and apparatus are disclosed for mobile device tethering for a remote parking assist system of a vehicle. An example vehicle includes a plurality of proximity sensors and a body control module. In response to detecting a mobile device proximate one of the proximity sensors, the body control module sends a location associated with the corresponding proximity sensor to the mobile device. The body control module receives, from the mobile device, a relative position of the mobile device from the location, and when the mobile device is within a threshold distance of the vehicle, enables autonomous parking.

In an aspect, false alerts in a collision avoidance system of an automotive vehicle are prevented when the vehicle is in reverse. The collision avoidance system includes at least an upper rear facing obstruction sensor and a lower rear facing obstruction sensor. When the vehicle is approaching a positive road grade change, the sensitivity of the lower rear facing obstruction sensor is reduced. In an aspect, an active rear view area of a rear facing vision system of the vehicle is adjusted when the vehicle is approaching a change in road grade.

Automated drive assisting systems, methods, and programs acquire an expected travel route for a vehicle that includes an automated drive section in which automated drive control for the vehicle is permitted, and execute the automated drive control for the vehicle such that the vehicle travels along the expected travel route in the automated drive section which is included in the expected travel route. The systems, methods, and programs make a changeover from the automated drive control to manual drive based on a drive operation by a user in the case where there is a branch point that meets a predetermined condition ahead in a travel direction of the vehicle which travels through the automated drive control in the automated drive section, the changeover being made before the branch point.

System, methods, and other embodiments described herein relate to implementing and calibrating a learning model for inferring operator intent by estimating grip intensity. In one embodiment, a method includes estimating, using a learning model during a driving scenario, first grip intensity on a steering device for a vehicle according to initial image data depicting a hand of an operator gripping outside set areas that have pressure sensors. The method also includes calibrating the learning model for the operator and the steering device using grip measurements and additional image data acquired from gripping inside the set areas. The method also includes computing, using the learning model during the driving scenario, second grip intensity outside the set areas on the steering device according to hand images acquired about the operator. The method also includes adapting a vehicle parameter of the vehicle according to the second grip intensity.

The invention relates to a motor vehicle assembly for protecting a sensor/transmitter of a driving assistance system comprising a protection device that partially surrounds the sensor/transmitter where the protection device includes a first subassembly (B) with a detection/transmission element positioned facing a sensor/transmitter's surface via which a signal passes, and a second subassembly (C) that includes a motor configured to rotatably drive the first subassembly (B) about a line of transmission/reception of the sensor/transmitter. According to the invention, the protection assembly includes at least one heating element controlled by a control unit that heats an accessory attached to the motor vehicle's body in the detection/transmission element's vicinity, the heating element being outside the protection device and in the vicinity of the first subassembly (B).

Systems and methods are directed to determining one or more angles and/or distances between at least first and second portions of a partially or fully autonomous vehicle. In one example, a system includes one or more processors and memory including instructions that, when executed by the one or more processors, cause the one or more processors to perform operations. The operations include obtaining sensor data. The operations further include determining at least one angle between a first portion and a second portion of an autonomous vehicle based at least in part on the sensor data. The operations further include determining at least one distance between the first portion and the second portion of the autonomous vehicle based at least in part on the sensor data. The operations further include providing the at least one angle and at least one distance for use in controlling operation of the autonomous vehicle.

A system includes an electro-dermal potential sensing system to sense electro-dermal potential of a person and configured to output an electro-dermal potential signal, as well as at least one physiological sensor to measure at least one physiological state and output at least one physiological signal. The system also includes a controller to receive the electro-dermal potential signal from the electro-dermal potential sensing system and the at least one physiological signal to determine a drowsiness state of the person.

A safety system for a vehicle includes cameras disposed at the driver side door and passenger side door of the vehicle and having respective fields of view exterior the vehicle. A control, responsive to processing at a processor of image data captured by the cameras, determines a potential hazardous condition at the driver side door and/or the passenger side door. The determined potential hazardous condition includes a determination that the driver-side door or the passenger-side door, when opening, will impact an object. Responsive to determination of the potential hazardous condition, the control controls the equipped vehicle to mitigate the potential hazardous condition by limiting opening of the respective driver-side door or the passenger-side door.

A vehicle having an electronic, automatic transmission incorporates a safety stop system. A position sensor or sensors are mounted onto the vehicle and are in communication with an electric controller. The electric controller in turn is operatively connected to the actuation solenoids in the hydraulic transmission. When a safety violation occurance is detected, then the electric controller either slows the speed of the vehicle or stops the vehicle through the transmission.