According to an embodiment, an information processing device includes a memory and processing circuitry. The processing circuitry is configured to acquire a map defining a target in a coordinate space in which a direction along a traveling direction of a moving object is one of coordinate axes, and approximate a movement rout of the moving objet with a specified shape area along a coordinate axis in the coordinate space, the specified shape area being a basic unit of collision determination.

A method for setting activation parameters for a vehicle safety system of a subject vehicle. The method includes determining whether a collision between a subject vehicle and an object is imminent or in progress. Whether the collision will be a front small overlap collision is determined, and activation parameters of a vehicle safety system are set in a front small overlap collision mode if the collision is determined to be a front small overlap collision.

A method is provided for selecting, by a driver, a road user, the road user being an evaluation object of a function of a driver assistance system of a motor vehicle, using at least one display device which displays the road user. After a first operating action is carried out, a search function is activated in which at least a subset of the shown road users is individually marked on the display device in a sequence containing all road users. When a second operating action is carried out, or after a predetermined first period of time, the currently-marked road user is selected as the evaluation object for the function.

The present invention provides a sensing apparatus for a vehicle, the apparatus including: a sensing unit that is configured to sense at least one of vehicle speed information, yaw rate information, and steering angle information, and to sense a forward object existing within a sensing distance set in advance; a calculator that is configured to calculate at least one of a driving curvature radius, which is calculated based on the vehicle speed information and the yaw rate information, and a steering angular speed, which is calculated based on the steering angle information; and an adjusting unit that is configured to adjust the sensing distance to be decreased when the driving curvature radius is less than, or equal to, a predetermined curvature radius or when the steering angular speed is less than, or equal to, a predetermined angular speed.

Techniques are disclosed for implementing a convolutional neural network that determines an offset field for deforming a kernel to be used in a convolution. The offset field is temporally-based, at least in part, on data generated at an earlier time. Furthermore, techniques are disclosed for using sensor data to train a neural network to learn shapes or configurations of such deformed kernels. The temporal-based deformable convolutions may be used for object identification, object matching, object classification, segmentation, and/or object tracking, in various examples.

Provided are a cruise control system and method for an autonomous apparatus having a Light Detection and Ranging (LIDAR) device. The cruise control system is implemented by at least one hardware processor and includes an input unit configured to receive scanning information from the LIDAR device, the scanning information related to peripheral environment of the autonomous apparatus; and a main controller configured to determine a scannable region of the peripheral environment and an unscannable region of the peripheral environment based on the scanning information, and to generate obstacle information by detecting a first sunken region in the scannable region and a second sunken region in the unscannable region.

Arrangements described herein provide adaptive cruise control systems that present travel settings for one or more nearby vehicles. Location information for one or more nearby vehicles can be acquired. Travel settings for the one or more nearby vehicles can be acquired. The travel settings can include a set speed and a set distance for each of the one or more nearby vehicles. Arrangements described herein can present within the vehicle the travel settings for the one or more nearby vehicles. A vehicle to follow from the one or more nearby vehicles can be selected based on the displayed travel settings.

The present invention describes a control system, which is adapted and determined to identify motor vehicles driving in front. The control system is at least adapted and determined to detect another motor vehicle participating in the traffic with the at least one environmental sensor. The control system is at least adapted and determined to determine positions of the other motor vehicle for a predetermined time interval. The control system is at least adapted and determined to determine at the end of the time interval whether a) a current position of the own motor vehicle lies ahead of at least one of the determined positions of the other motor vehicle; b) a lateral distance between a respectively next position of the determined positions of the other motor vehicle ahead of and behind the current position of the own motor vehicle does not exceed a predetermined value; and c) a number of the determined positions of the other motor vehicle, which are located ahead of the current position of the own motor vehicle, exceeds a predetermined minimum number. The control system is at least adapted and determined to estimate a trajectory from the determined positions of the other motor vehicle if it was determined that a), b) and c) have been fulfilled. The control system is at least adapted and determined to select the other motor vehicle in order to follow this, based on a deviation measurement between the estimated trajectory of the other motor vehicle and a trajectory of the own motor vehicle.

A vehicle having an electronic, automatic transmission incorporates a safety stop system. A position sensor or sensors are mounted onto the vehicle and are in communication with an electric controller. The electric controller in turn is operatively connected to the actuation solenoids in the hydraulic transmission. When a safety violation occurance is detected, then the electric controller either slows the speed of the vehicle or stops the vehicle through the transmission.

A travel control device is equipped with an acceleration/deceleration control unit that executes an acceleration/deceleration control to automatically carry out acceleration and deceleration of a host vehicle, and a departure suppression unit which, when it is determined that a future or actual departure of the host vehicle with respect to a travel lane of the host vehicle will occur or is occurring, executes a departure suppression control to carry out a departure suppression process to suppress the future or actual departure. The acceleration/deceleration control unit limits acceleration of the host vehicle when the departure suppression process is initiated.