Abstract: A method for determining a location of a vehicle. The method includes steps of acquiring a plurality of sensor data from a radar sensor associated with the vehicle; obtaining an approximate location of the vehicle using a GPS unit; comparing the sensor data to a database of geo-referenced sensor data; and based on the comparison, determining a location of the vehicle.

Abstract: A system for identifying a route to be traveled by an oversized vehicle. The system includes a measurement vehicle having at least one sensor attached thereto, wherein the measurement vehicle travels one or more potential routes on a roadway, and a controller in communication with the at least one sensor. The controller is configured to collect data from the at least one sensor, the data providing information regarding at least one of a location, height, shape, and classification of each of a plurality of objects on or adjacent to the roadway and generate a map of the one or more potential routes traveled by the measurement vehicle.

Abstract: A regenerative braking system for a vehicle. The system includes at least one detecting device or sensor, and an electronic control unit having a processor and a computer readable medium. The sensor detects information about at least one target object located ahead of the vehicle. The electronic control unit is in electronic communication with the sensor to receive the information about the at least one target object and stores instructions that, when executed by the processor, cause the processor to: receive information about a velocity of the vehicle, determine a velocity of the at least one target object based on the information from the at least one detection device, determine a maximum deceleration of the vehicle that can be reached by the regenerative braking system without applying physical brakes of the vehicle, and determine an optimal braking point to begin maximum regenerative braking.

Abstract: A collision warning device for motor vehicles includes: a locating system for locating objects in the area in front of the vehicle; a control device for evaluating the data of the locating system and for outputting a warning signal in the event of an imminent risk of a collision; and a detection module for detecting the course of guardrails with the aid of the data of the locating system. In the control device an additional warning function is implemented, which calculates, with the aid of the dynamic state of the vehicle and with the aid of the detected guardrail course, a parameter for the transverse dynamics of the vehicle, which is required to avert a collision with the guardrail, and which outputs a warning signal when this parameter is larger than a predefined value.

Abstract: A system for detecting objects in the blind spot of a host vehicle. When an object is detected in the blind spot of the host vehicle, the system analyzes other objects directly in front of or behind the detected object in the blind spot. If the other objects are moving, the system concludes that the object in the blind spot is also moving and, therefore, is a stagnating vehicle. If the other objects are not moving, the system concludes that the object in the blind spot is also a stationary object. The system generates a blind-spot-detection signal when it determines that a stagnating vehicle is located in the blind spot.

Abstract: A driver assistance system that includes a RADAR system, a video system, a brake control unit, and a controller, such as an engine control unit. The RADAR system is mounted on the front of the vehicle and is positioned to detect the location of various objects. The video system captures video images. The controller receives data from both the RADAR system and the video system and identifies objects and their locations based on both the RADAR and the video data. The controller then adjusts the operation of the engine and the vehicle brakes based on the identified objects and their locations. In some embodiments, the driver assistance system also includes a human-machine interface that notifies the driver when an object is identified and located.

Abstract: A collision warning device for motor vehicles includes a locating sensor, a lane recognition module for detecting the number of traffic lanes in the road on which the vehicle is traveling, and a decision unit to output a warning signal if a danger parameter (ttc) determined using the data from the locating sensor exceeds a threshold value, the threshold value being variable depending on the number of traffic lanes in such a way that the warning signal is issued earlier when the number of lanes is greater.

Abstract: An adaptive cruise control system for a host vehicle. The adaptive cruise control system includes a sensor and a controller. The sensor is configured to detect a vehicle in front of the host vehicle. The controller receives an indication of the detected vehicle from the sensor and is configured to maintain a speed of the host vehicle at a desired speed, to determine a speed of the detected vehicle relative to the host vehicle, and adjust an acceleration rate of the host vehicle based on the relative speed.

Abstract: Method for determining a dynamic variable representative for a lateral movement of a located object in a driver assistance system for motor vehicles, which has two angle-resolving distance sensors situated laterally offset to one another for locating the object, using which a radial component of the relative velocity of the object along the particular line of sight is also measurable, wherein the dynamic variable is calculated on the basis of the radial components of the relative velocity measured by the two distance sensors.

Abstract: In a method for operating a radar system and a radar system for performing the method, in particular a microwave radar system for applications in or on motor vehicles, in which at least one target object and at least one possible concealing object are detected using radar technology, it is provided in particular that a detection is made of whether a concealment situation of the at least one target object by the at least one concealing object exists, and in the case of a detected concealment situation a loss of the target object is not automatically assumed.

Abstract: A collision warning device for motor vehicles includes: a locating system for locating objects in the area in front of the vehicle; a control device for evaluating the data of the locating system and for outputting a warning signal in the event of an imminent risk of a collision; and a detection module for detecting the course of guardrails with the aid of the data of the locating system. In the control device an additional warning function is implemented, which calculates, with the aid of the dynamic state of the vehicle and with the aid of the detected guardrail course, a parameter for the transverse dynamics of the vehicle, which is required to avert a collision with the guardrail, and which outputs a warning signal when this parameter is larger than a predefined value.

Abstract: A cover assembly is provided for a vehicle-mounted device having an alignment feature on a face of the device. The cover assembly includes a rod portion, a securing arrangement coupled to the rod portion to secure the cover assembly to the device, and a cover portion coupled to the rod portion and configured to cover the alignment feature on the face of the device.

Abstract: A collision warning device for motor vehicles includes a locating sensor, a lane recognition module for detecting the number of traffic lanes in the road on which the vehicle is traveling, and a decision unit to output a warning signal if a danger parameter (ttc) determined using the data from the locating sensor exceeds a threshold value, the threshold value being variable depending on the number of traffic lanes in such a way that the warning signal is issued earlier when the number of lanes is greater.

Abstract: A method for recognizing a vertical misalignment of the radiation characteristic of a radar sensor of a control system for a motor vehicle, in particular of a driving speed and/or adaptive driving speed system, including the following steps: the receive power of the radar radiation reflected from an object is determined; the distance dependence and the horizontal angular dependence are compensated according to the radar equation; the functional dependence of the receive power, processed in this way, on the distance from the object is compared to an expected and stored curve of the receive power over the distance, and from this the vertical misalignment of the radiation characteristic of the radar sensor is inferred.

Abstract: An adaptive cruise controller having dynamics matching as a function of the situation includes an identification device for identifying various predefined categories of single-file driving situations, and for selecting a dynamic profile matched to the situation identified.

Abstract: Method for determining a dynamic variable representative for a lateral movement of a located object in a driver assistance system for motor vehicles, which has two angle-resolving distance sensors situated laterally offset to one another for locating the object, using which a radial component of the relative velocity of the object along the particular line of sight is also measurable, wherein the dynamic variable is calculated on the basis of the radial components of the relative velocity measured by the two distance sensors.