In some examples, a controller receives information of a route of a vehicle, and selects a first parameter set from among a plurality of parameter sets based on the route of the vehicle, the plurality of parameter sets corresponding to different conditions of usage of the vehicle, where each parameter set of the plurality of parameter sets includes one or more parameters that control adjustment of one or more respective adjustable elements of the vehicle. The controller causes application of the first parameter set to control a setting of the one or more adjustable elements of the vehicle.

Techniques and methods for performing collision monitoring using system data. For instance, a vehicle may generate sensor data using one or more sensors. The vehicle may then analyze the sensor data using systems in order to determine parameters associated with the vehicle and parameters associated with another object. Additionally, the vehicle may determine uncertainties associated with the parameters and then process the parameters using the uncertainties. Based at least in part on the processing, the vehicle may determine a distribution of estimated locations associated with the vehicle and a distribution of estimated locations associated with the object. Using the distributions of estimated locations, the vehicle may determine the probability of collision between the vehicle and the object.

Embodiments of the present invention provide computer-implemented methods, computer program products and systems. Embodiments of the present invention can receive position and location information. Embodiments of the present invention can generate a risk score for one or more maneuvers associated with a predicted trajectory of a vehicle. Embodiments of the present invention can generate a visual representation for each of the one or more maneuvers associated with the predicted trajectory of the vehicle based on the generated risk score associated with each maneuver. Embodiments of the present invention can integrate the generated visual representation into a user display.

A driving supporter includes: an object-information obtainer that obtains object information relating to at least an object in an area; an environment obtainer that obtains a relative positional relationship between the own vehicle and the object located in the area and identified based on the object information obtained by the object-information obtainer; and a support inhibitor that inhibits driving support when an absolute value of a steering operation value representing a magnitude of a steering operation is greater than an inhibition threshold value. The support inhibitor includes a threshold-value determiner that determines the inhibition threshold value to a smaller value when the relative positional relationship is a specific relationship in which it is estimated that a steering operation in a direction in which the own vehicle avoids the object is to be performed, than when the relative positional relationship is not the specific relationship.

This document describes methods by which a system determines a pickup/drop-off zone (PDZ) to which a vehicle will navigate to perform a ride service request. The system will define a PDZ that is a geometric interval that is within a lane of a road at the requested destination of the ride service request by: (i) accessing map data that includes the geometric interval; (ii) using the vehicle's length and the road's speed limit at the destination to calculate a minimum allowable length for the PDZ; (iii) setting, start point and end point boundaries for the PDZ having an intervening distance that is equal to or greater than the minimum allowable length; and (iv) positioning the PDZ in the lane at or within a threshold distance from the requested destination. The system will then generate a path to guide the vehicle to the PDZ.

An autonomous driving control apparatus and method are for determining following-route deviation of an autonomous vehicle. The apparatus and method: may obtain surrounding information of an autonomous vehicle; may calculate a control-following route according to a predetermined driving strategy based on the surrounding information and the high definition map information around an autonomous vehicle; may calculate an expected driving route on which the autonomous vehicle is expected to be driven, when autonomous driving according to the control-following route is performed; may determine whether following-route deviation of the autonomous vehicle is expected, by comparing the control-following route with the expected driving route; and may change the driving strategy based on whether the following-route deviation of the autonomous vehicle is expected.

A vehicular trailer sway management system includes at least one rearward-sensing radar sensor disposed at a vehicle and an electronic control unit (ECU). Radar data captured by the at least one rearward-sensing radar sensor is provided to the ECU. With a trailer hitched to the vehicle, the trailer sway management system, via processing at the ECU of the provided captured radar data, determines oblique angles of the trailer relative to the vehicle. As the vehicle tows the trailer, and responsive to monitoring of determined oblique angles of the trailer relative to the longitudinal axis of the vehicle, the trailer sway management system determines sway of the trailer relative to the vehicle. Responsive to the determined sway of the trailer relative to the vehicle, the trailer sway management system at least in part controls operation of the vehicle to manage sway of the trailer relative to the vehicle.

Various technologies described herein pertain to causing presentation on a user interface of an immediate portion of a navigation route of an autonomous vehicle. A computing system of the autonomous vehicle determines whether an object detected by sensor(s) of the autonomous vehicle proximate to the immediate portion of the navigation route are of a type and relative position defined as one of consequential and inconsequential for a human passenger. In response to determining that an object has both a type and relative position defined as consequential, the computing system causes presentation on the user interface a representation of the object relative to the immediate portion of the navigation route to provide a confidence engendering indication that the autonomous vehicle has detected the object. Otherwise if inconsequential, presentation on the user interface of any representation of the object is not caused by the computing system to avoid creating a confusing presentation.

In order to process sensor data for a driver assistance system oriented towards the driver's comfort, sensor data that is sensed by a sensor device and describes objects is preprocessed such that a distinction is made between a driving zone and a non-driving zone, where the driving zone is designated as an object driving zone. The object driving zone is delimited by a boundary line. Since the sensor data is processed for a comfort-oriented driver assistance system, it does not have to describe the entire theoretical driving zone. Rather, the boundary line is used to delimit the driving zone within which the vehicle can normally be expected to drive. Based thereon, it is easy to determine an appropriate boundary line and significantly reduce the volume of data to be transmitted from the sensor device to a central control device of the comfort-oriented driver assistance system in order to describe the sensed objects.

A parking assistance system executes a process to measure the parking space by a sensor prior to carrying out an automated parking maneuver and to detect the parking space type from a plurality of detectable parking space types using specific criteria on the basis of the measurement of the parking space. The plurality of parking space types includes a longitudinal parking space type, in which a vehicle can park longitudinally, a transverse parking space type, in which a vehicle can park transversely, and a universal parking space type in which the vehicle can park both longitudinally as well as transversely. In the event that the parking space has been detected as a universal parking space type, the parking assistance system provides the driver with the choice to select a parking direction, namely whether the parking assistance system is to park longitudinally or transversely into the parking space. The parking assistance system parks the vehicle into the parking space longitudinally or transversely according to the selection of the driver, wherein the parking trajectory depends on the selection of the driver.