Abstract: A system, method, and computer-readable medium having instructions stored thereon to enable an ego vehicle having an autonomous driving function to estimate and traverse a curved segment of highway utilizing radar sensor data. The radar sensor data may comprise stationary reflections and moving reflections. The ego vehicle may utilize other data, such as global positioning system data, for the estimation and traversal. The estimation of the curvature may be refined based upon a lookup table or a deep neural network.

Abstract: A system, method, and computer-readable medium having instructions stored thereon to enable an ego vehicle having an autonomous driving function to estimate and traverse a curved segment of highway utilizing radar sensor data. The radar sensor data may comprise stationary reflections and moving reflections. The ego vehicle may utilize other data, such as global positioning system data, for the estimation and traversal. The estimation of the curvature may be refined based upon a lookup table or a deep neural network.

Abstract: A system, method, and computer-readable medium having instructions stored thereon to enable an ego vehicle having an autonomous driving function to estimate and traverse a curved segment of highway utilizing radar sensor data. The radar sensor data may comprise stationary reflections and moving reflections. The ego vehicle may utilize other data, such as global positioning system data, for the estimation and traversal. The estimation of the curvature may be refined based upon a lookup table or a deep neural network.

Abstract: Adaptive cruise control systems and methods of providing overtake acceleration aid in host vehicles. In one embodiment, the adaptive cruise control system includes an ultrasonic sensor, a radar sensor, a camera, and an electronic controller. The ultrasonic sensor, the radar sensor, and the camera are configured to sense within fields-of-view of a neighboring lane. Responsive to receiving an input indicating an overtake request, the electronic controller is configured determine when an object is located in the neighboring lane based in part on first data received from the ultrasonic sensor. The electronic controller is also configured to determine a velocity of the object when the object is located within the field-of-view of the radar sensor or the camera. The electronic controller is further configured to determine an overtake acceleration boost based in part on the velocity of the object and apply the overtake acceleration boost to the host vehicle.

Abstract: Adaptive cruise control systems and methods of providing overtake acceleration aid in host vehicles. In one embodiment, the adaptive cruise control system includes an ultrasonic sensor, a radar sensor, a camera, and an electronic controller. The ultrasonic sensor, the radar sensor, and the camera are configured to sense within fields-of-view of a neighboring lane. Responsive to receiving an input indicating an overtake request, the electronic controller is configured determine when an object is located in the neighboring lane based in part on first data received from the ultrasonic sensor. The electronic controller is also configured to determine a velocity of the object when the object is located within the field-of-view of the radar sensor or the camera. The electronic controller is further configured to determine an overtake acceleration boost based in part on the velocity of the object and apply the overtake acceleration boost to the host vehicle.