A longitudinal control system is provided for a motor vehicle equipped with a sensor system for detecting a traffic event lying ahead, in particular in order to locate vehicles traveling ahead, and a control unit for automatically controlling the speed or the acceleration of the motor vehicle to a standstill on the basis of the traffic event lying ahead. An automatic drive-off is allowed without a driver confirmation within a specified time interval after reaching the standstill, and after the time interval has expired, an automatic start-up is allowed after a start-up confirmation is triggered by the driver. A start-up confirmation is triggered if a contacted state of the steering wheel is detected starting from a non-contacted state of the steering wheel.

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.

A vehicle floor assembly includes a floor structure and a capacitive proximity sensor assembly configured to detect a user touch command and a user pressure command. The floor assembly further includes a controller for receiving the user touch command and pressure command and controlling a vehicle related operation based on the detected user input commands.

A vehicle floor assembly includes a floor structure and a capacitive proximity sensor assembly configured to detect a user touch command and a user pressure command. The floor assembly further includes a controller for receiving the user touch command and pressure command and controlling a vehicle related operation based on the detected user input commands.

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.

This disclosure is generally directed to systems and methods for detecting a water depth level using capacitive sensors. The systems and methods disclosed herein receive a first capacitive signal from a first capacitive sensor in a wheel well of a vehicle. The systems and methods may determine that the first capacitive signal is not below a threshold value. The systems and methods display an image in a cab of the vehicle, wherein the image corresponds to a water depth level associated with the first capacitive signal. The systems and methods receive a second capacitive signal from a second capacitive sensor corresponding to a rising water level. The systems and methods display a warning message, on a display, indicating the rising water level.

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.

This disclosure is generally directed to systems and methods for detecting a water depth level using capacitive sensors. The systems and methods disclosed herein receive a first capacitive signal from a first capacitive sensor in a wheel well of an autonomous vehicle (AV) and determine that the first capacitive signal exceeds a threshold value. The AV controller may be configured to determine water levels using a capacitive sensor system, and perform mitigating actions that cause the vehicle to either clean soiled capacitive sensors, or move the vehicle to a location that mitigates the risk of vehicle damage. Other mitigating actions may be performed as well, including disabling or powering down critical vehicle components when the vehicle cannot be moved to another location, providing means for emergency vehicle exit, and sending warning messages to the fleet control server, to occupants of the AV, or to other emergency personnel.

Technologies and techniques for automatically generating labeled steering torque data, with which an artificial intelligence (AI) unit is trained to detect hands-off conditions when the vehicle is being operated.

A program and a control device capable of calibrating a detection value of a sensor that detects contact with a steering wheel are provided. The program in accordance with the present invention is characterized by causing a computer to execute processing of distinguishing whether or not a user is on a driver's seat of a vehicle; acquiring, from a sensor (21) that converts contact with a steering wheel (2) into an electric signal for detection, a detection value of the detected electric signal; determining whether or not a difference between the detection value acquired when it has been distinguished that the user is not on the driver's seat, and a reference value is equal to or larger than a threshold value; and setting the detection value as the reference value when it has been determined that the difference is not equal to or larger than the threshold value.