A method for locating a vehicle, including the following steps: sensorial detection of first surroundings objects by the vehicle; locating the vehicle by reconciling data of the sensorially detected first surroundings objects with map data of a first digital map, in the case in which reconciliation of the data of the first surroundings objects with the map data of the first digital map to a defined extent is not possible, a second digital map for a local surroundings of the vehicle being created and location of the vehicle being carried out using the second digital map, data from second surroundings objects of an ascertaining device, which are conveyed from the ascertaining device to the vehicle, being used for creation of the second digital map.

A vehicle system includes a high voltage battery and at least one control module configured to monitor the high voltage battery and command a visual warning in response to a disconnect event of the high voltage battery. The visual warning may be produced by a hazard light.

A host vehicle has an automatic brake control that is executed for avoiding contact between the host vehicle and a pedestrian upon detecting a pedestrian is present in a forward position of the host vehicle using a front camera and a radar. In a driving assist control method, upon detecting an object in front of the host vehicle to be a pedestrian candidate based on an image signal from the front camera, execution of an automatic brake control is permitted with the detected pedestrian candidate as the control target. Thereafter, whether or not the pedestrian candidate detected by the front camera matches an object detected by the reflected waves from the millimeter wave radar is determined by comparison. Execution of the automatic brake control is continued or stopped based on the result of the comparison determination.

A system and method may track data from one or more sensors during vehicle driving. Based on the sensors data, one or more alerts or potential hazards may be identified. The system and method may generate a drive summary including information and optional statistics about the alerts or potential hazards.

A method according to the present invention includes calculating, based on a reported position of a vehicle, a probability that an actual position of the vehicle is within a region of interest. The method further includes determining whether a threat of a collision exists between the vehicle and an object based on the probability that the actual position of the vehicle is within the region of interest and a reported position of the object. The method further includes generating an alert if it is determined a threat of a collision exists between the vehicle and the object.

Systems and methods for dynamically assessing vehicle operation are described. According to certain aspects, an electronic device may accumulate telematics data associated with operation of a vehicle, where the telematics data indicates a location of the vehicle. The electronic device may retrieve additional telematics data of additional vehicles operating at or near the location, and compare the accumulated telematics data to the additional telematics data. The electronic device may dynamically generate and display a data visualization indicating the analysis for review by an operator of the vehicle.

A driving assist ECU which performs collision avoidance control for the target based on a detection result of a target around an own vehicle by a radar device acquires, at a predetermined cycle, angle deviation information of the radar device in the vertical direction, the angle deviation information being calculated from a detection position of the target, and calculates an axis deviation angle by performing statistical processing of a history of the angle deviation information acquired after activation, the axis deviation angle being a deviation amount of a mounting angle of the radar device in the vertical direction. Until a predetermined initial time period elapses after the activation, a limitation is imposed on the collision avoidance control for, among targets detected by the radar device, a stationary target which is a target corresponding to a stationary object.

In some examples, a ground obstacle detection system of an aircraft is configured to generate and display a graphical user interface (GUI) that includes a graphical representation of a detected obstacle with which the aircraft may collide during a ground operation and an indication of an area of unknown associated with the detected obstacle. Instead of, in addition to, a GUI that includes an indication of an area of unknown associated with an obstacle, in some examples, a ground obstacle detection system to generate a GUI that includes at least two windows that present different views of an aircraft. At least one of the windows may include a graphical representation of an obstacle that may not be visible in the view of another window.

A radio signal path design tool that allows radio link propagation path profiling or path-loss measurement where the link partner antenna towers are located in a proposed fixed location on the earth's surface, but are extendable a certain distance in any direction from the fixed location. The design tool can be used to compute a radio link path profile at the proposed tower location, while still correctly representing terrain variations in a variable path extension distance on either side of the radio link. To correctly represent terrain variations across the depicted portion of the earth's surface, the tool computes and applies a modified earth-bulge factor or k-factor. The variable extension distance on either side of the radio link allows for latitudinal and/or longitudinal variations in antenna tower placement, greatly facilitating the identification of appropriate positions of antenna towers during the wireless link design phase.

A radio signal path design tool that allows radio link propagation path profiling or path-loss measurement where the link partner antenna towers are located in a proposed fixed location on the earth's surface, but are extendable a certain distance in any direction from the fixed location. The design tool can be used to compute a radio link path profile at the proposed tower location, while still correctly representing terrain variations in a variable path extension distance on either side of the radio link. To correctly represent terrain variations across the depicted portion of the earth's surface, the tool computes and applies a modified earth-bulge factor or k-factor. The variable extension distance on either side of the radio link allows for latitudinal and/or longitudinal variations in antenna tower placement, greatly facilitating the identification of appropriate positions of antenna towers during the wireless link design phase.