Systems and methods are provided for determining a road profile along a predicted path. In one implementation, a system includes at least one image capture device configured to acquire a plurality of images of an area in a vicinity of a user vehicle; a data interface; and at least one processing device configured to receive the plurality of images captured by the image capture device through the data interface; and compute a profile of a road along one or more predicted paths of the user vehicle. At least one of the one or more predicted paths is predicted based on image data.

A target-lane relationship recognition apparatus mounted on a vehicle includes a sensor that detects a situation around the vehicle, a memory device in which a map data indicating a boundary position of a lane on a map is stored, and a processing device. The processing device is configured to: (a) acquire, based on the sensor detection result, target information regarding a moving target and a stationary target around the vehicle; (b) acquire, based on the map data and position-orientation of the vehicle, lane geometry information indicating a lane geometry around the vehicle; (c) adjust the lane geometry to generate an adjusted lane geometry satisfying a condition that the moving target is located within a lane and the stationary target is located outside of any lane; and (d) generate target-lane relationship information indicating a positional relationship between the moving target and the adjusted lane geometry.

A vehicular driving assist system includes a forward-viewing camera and a side object detection system disposed at a vehicle equipped with the vehicular driving assist system. The side object detection system includes a driver side-sensing radar sensor and a passenger side-sensing radar sensor. Image data captured by the forward-viewing camera is processed to detect traffic lane markers for a lane departure warning system of the equipped vehicle. Responsive at least in part to one of the radar sensors detecting a vehicle travelling in the same direction as the equipped vehicle and approaching from rearward of the equipped vehicle in a traffic lane that is to the respective side of the traffic lane that the equipped vehicle is travelling in, the vehicular driving assist system alerts a driver of the equipped vehicle of presence of the detected vehicle regardless of turn signal usage by the driver of the equipped vehicle.

A method is disclosed for use in a planning agent, the method including: identifying a first agent in a vicinity of the planning agent; identifying a location of the first agent and a velocity of the first agent; calculating a set of occupancy costs for the first agent, each occupancy cost in the set of occupancy costs being associated with a different respective location in the vicinity of the planning agent, each occupancy cost in the set of occupancy costs being calculated at least in part based on a cost function that depends on the location of the first agent and the velocity of the first agent; and changing at least one of speed or direction of travel of the planning agent based on the set of occupancy costs.

A driver assist analysis system includes a processing system and a database that stores vehicle data, vehicle operational data, vehicle accident data, and environmental data related to the configuration and operation of a plurality of vehicles with driver assist systems or features. The driver assist analysis system also includes one or more analysis engines that execute on the processing system to determine one or more driving anomalies (e.g., accidents or poor driving operation) based on the vehicle operational data, and that correlate or determine a relationship between the driving anomalies and the operation of the driver assist systems or features. The driver assist analysis system then determines an effectiveness of operation of one or more of the driver assist systems or features as a statistical measure based on the determined relationship and the driver assist analysis system notifies a user or receiver, such as a manufacturer or an insurance company of the statistical measure.

Systems and methods are provided for navigating a host vehicle. A navigation system for the host vehicle may include at least one processor programmed to receive an image representative of an environment of a host vehicle; analyze the image to determine a predicted path of the host vehicle; determine, based on the image, an indicator of comfort associated with the predicted path; identify, based on the indicator of comfort, an alternative path of the host vehicle; and output a control signal configured to modify an operation of a component of the host vehicle to follow the alternative path of the host vehicle.

An apparatus for controlling an autonomous vehicle brake, including a first brake controller configured to control a brake module of an autonomous vehicle by receiving a deceleration command from an autonomous controller for controlling autonomous driving of the autonomous vehicle, and a second brake controller configured to control the brake module of the autonomous vehicle by receiving a deceleration command from the autonomous controller. The first and second brake controllers exchange monitoring information with each other in a predetermined communication manner to monitor an operation state, so that control of the brake module is transferred according to the result of monitoring.

A safety system for a vehicle providing a road departure protection feature comprises a camera, mounted to the vehicle to provide a view of a driving direction of the vehicle, and an electronic control unit connected to the camera. The electronic control unit includes instructions for analyzing the image and comparing the roadway path to the predicted vehicle path. The electronic control unit determines a vehicle roadway departure is occurring when the predicted vehicle path differs from the roadway path by a predetermined threshold, and then determines at least one corrective action to return the vehicle path to the roadway path. The safety system sends instructions to apply at least one corrective action with at least an electronic stability control system.

To provide a device for controlling vehicle travel with which it is possible, when a host vehicle has malfunctioned, to prevent accidents and secondary disasters caused by the vehicle malfunction. The device for controlling travel is provided with: a malfunction detector for detecting the presence/absence of malfunctions in a variety of devices for assisting the driving of the host vehicle; a malfunction degree determining unit for specifying, when the malfunction detector detects a malfunction in any of the devices, the malfunction state of the device and determining whether or not the device can be driven; and an action instruction unit for generating, on the basis of determination information from the malfunction degree determining unit, an instruction signal for communicating an action instruction for another vehicle, and outputting the instruction signal out of the host vehicle.

The present invention provides a vehicle control device in which it is possible to modify the travel trajectory of a vehicle in response to the presence of an obstruction in the vehicle perimeter. In the present invention, the vehicle control device 1 recognizes the surroundings of the vehicle, detects a first branching point in a first route that is preset on a road, and in cases in which a prescribed condition is met by the presence of an obstruction detected from the recognized surroundings when the vehicle is to move along a travel trajectory that is based on at least one second route from among a plurality of second routes that branch from the first branching point, generates a virtual route which branches from the first route at a second branching point differing from the first branching point toward the selected second route, and modifies the travel trajectory on the basis of the generated virtual route.