Systems and methods for driver presence and position detection are disclosed herein. A method can include determining a presence and a position of a driver in a sensing zone of a vehicle using a sensor platform integrated into the vehicle, determining when the position of the driver indicates that the driver is not in a fully-seated position relative to a driver's seat of the vehicle, and selectively adjusting a vehicle parameter of the vehicle based on the driver not being in a fully-seated position.

A driver assistance system is provided in a motor vehicle, which driver assistance system executes at least active transverse guidance interventions. The driver assistance system can be activated while decoupled from the activation of a longitudinal control system but can also be active both, with and without longitudinal control, and includes both a traffic jam assistance sub-function and a track guiding assistant sub-function. The two sub-functions can be jointly activated and deactivated by a single on-/off-button. The driver assistance system is characterized by a special combination of the sub-functions track guiding assistance and traffic jam assistance. They each take turns depending on the presence of conditions, which are defined differently for each sub-function.

A system, vehicle, method and non-transitory computer readable storage medium for improving driving safety are provided. The system includes: a steering wheel; a paddle attached to the steering wheel; a pressure sensor, which is installed between the paddle and a contact point of the paddle to the steering wheel and is coupled to a control component, wherein the pressure sensor is configured to sense a pressure exerted on the pressure sensor by the paddle and send the sensed pressure to the control component; and the control component, which is configured to, in responsive to receiving the sensed pressure, determine a level of deceleration corresponding to the sensed pressure and send a deceleration command which instructs to decelerate, based on the determined level of deceleration, a vehicle on which the system for improving the driving safety is installed.

A vehicle assembly includes a sensor system of a bumper or a skid plate. The sensor system includes a plurality of first sensors and at least one second sensor. The sensor system emits a first electrical field from each of the first sensors when the plurality of first sensors are active and the at least one second sensor is inactive. The sensor system emits a second electrical field when the plurality of first sensors are active and the at least one second sensor is active. The first electrical field projects a first distance from the skid plate. The second electrical field projects a longer, second distance from the skid plate.

A speed based alarm system to be used in automobiles includes a first touch sensor, a second touch sensor, a processing unit, and a notification alarm. The first touch sensor and the second touch sensor are integrated into a steering wheel body of an automobile to detect the hands of the driver on the steering wheel. The feedback from the first touch sensor and/or the second touch sensor are received at the processing unit along with a vehicle speed, wherein the vehicle speed is retrieved from a vehicle logic board. The processing unit determines if the automobile is at a speed which requires both hands of the driver for better control of the automobile. If the automobile is at a speed that requires both hands of the driver, and only one hand is detected on the steering wheel, the processing unit activates the notification alarm to notify the driver.

A system, vehicle, method and non-transitory computer readable storage medium for improving driving safety are provided. The system includes: a steering wheel; a paddle attached to the steering wheel; a pressure sensor, which is installed between the paddle and a contact point of the paddle to the steering wheel and is coupled to a control component, wherein the pressure sensor is configured to sense a pressure exerted on the pressure sensor by the paddle and send the sensed pressure to the control component; and the control component, which is configured to, in responsive to receiving the sensed pressure, determine a level of deceleration corresponding to the sensed pressure and send a deceleration command which instructs to decelerate, based on the determined level of deceleration, a vehicle on which the system for improving the driving safety is installed.

A vehicular driving assist system includes a camera disposed in a vehicle and at least viewing driver hand positions of hands of a driver present in the vehicle. The vehicular driving assist system determines driver hand positions via processing of image data captured by the camera. The vehicular driving assist system compares determined driver hand positions to a plurality of discrete driver hand positions, which includes (i) a plurality of discrete driver hand positions at a steering wheel of the vehicle, and (ii) a plurality of discrete driver hand positions at an interior portion of the vehicle and not at the steering wheel of the vehicle. The vehicular driving assist system, responsive to processing of image data captured by the camera and based at least in part on comparison of determined driver hand positions to the plurality of discrete driver hand positions, determines a level of attentiveness of the driver.

In accordance with an exemplary embodiment, a method is provided that includes: obtaining sensor data via one or more sensors of a vehicle; determining, via a processor of the vehicle, a driving style of a driver of the vehicle based on use of the sensor data over multiple periods of time; and determining, via the processor, an indication as to whether the driver is attempting to spoof a control system of the vehicle with respect to one or more automated features of the vehicle, based on the sensor data and the style of the driver.

In one or more embodiments, a method comprises receiving, at a processor, sensor data from a sensor at a vehicle that is moving while in an autonomous mode. A position and an orientation of the vehicle based on the sensor data is determined at the processor. A lateral deviation of the vehicle from a planned path based on the position and the orientation of the vehicle while the vehicle is moving in the autonomous mode is calculated at the processor. In response to the lateral deviation exceeding a predefined lateral deviation threshold, the autonomous mode is disengaged.

A computer includes a processor and a memory storing instructions executable by the processor to determine, for a host vehicle operating in a first operation mode, a first operation mode transition location based on a time to transition the host vehicle from the first operation mode to a second operation mode, a current speed of the host vehicle, and a distance from the host vehicle to an operation mode transition boundary location, to determine a second operation mode transition location that is a specified distance from the first operation mode transition location, the specified distance based on the current host vehicle speed, to transition from the first operation mode to the second operation mode upon reaching the first operation mode transition location, and to transition from the second operation mode to the first operation mode when the second operation mode transition location is between a current location of the host vehicle and the operation mode transition boundary location.