Patent application number | Description | Published |
20090138168 | Method for Operating A Cruise Control System for A Vehicle - A method for operating a cruise control system for a vehicle. The method can identify certain low speed environments, like parking lots, where usage of the cruise control system is usually inappropriate and can disable the system accordingly. According to one embodiment, a full speed range adaptive (FSRA) cruise control system compares a steering wheel position to a steering wheel threshold to determine if the vehicle is operating in an inappropriate low speed environment and, if so, disables the cruise control system accordingly. | 05-28-2009 |
20110025548 | SYSTEM AND METHOD FOR VEHICLE SENSOR FUSION - A system and method is provided for tracking and evaluating targets sensed by one or more active safety sensors in a motor vehicle. The system and method tracks detected targets from one or more sensors as fused tracks, and determines the maturity and plausibility of such fused tracks in determining an appropriate response. This facilitates the reliable detection and evaluation of targets based on sensor data from different sensors. | 02-03-2011 |
20110060478 | VEHICULAR TERRAIN DETECTION SYSTEM AND METHOD - Methods and system are provided for detecting attributes of a terrain surrounding a vehicle. The system includes at least one terrain sensor configured to generate data describing the terrain and a processor coupled to the at least one terrain sensor. The processor is configured to detect at least one attribute of the terrain based on data generated by the at least one terrain sensor and to adjust a handling behavior of the vehicle based on the at least one terrain attribute. | 03-10-2011 |
20110196568 | VEHICLE SAFETY SYSTEMS AND METHODS - Safety systems and methods are provided for use in a vehicle with a closure that defines a pivoting range when open. The safety system includes a sensor configured to collect data associated with an object in a target zone at least partially surrounding the vehicle; and a processor coupled to the sensors and configured to selectively operate in a first mode and a second mode based on a vehicle characteristic. The processor is configured to, in the first mode, detect the object and generate a first warning based on the object; and in the second mode, detect the object and determine a collision threat between the object and the pivoting range of the closure, and generate a second warning based on the collision threat. | 08-11-2011 |
20120065858 | VEHICLE SAFETY SYSTEMS AND METHODS - A safety system is provided for use in a first vehicle at a first location. The safety system includes a position unit configured to determine the first location; a sensor group configured to detect an opening of the enclosure; a controller coupled to the position unit and the sensor group, the controller configured to generate a warning message including the first location when the opening of the enclosure is detected; and a transmitter coupled to the controller and configured to transmit the warning message. | 03-15-2012 |
20120290169 | NOVEL SENSOR ALIGNMENT PROCESS AND TOOLS FOR ACTIVE SAFETY VEHICLE APPLICATIONS - A method and tools for virtually aligning object detection sensors on a vehicle without having to physically adjust the sensors. A sensor misalignment condition is detected during normal driving of a host vehicle by comparing different sensor readings to each other. At a vehicle service facility, the host vehicle is placed in an alignment target fixture, and alignment of all object detection sensors is compared to ground truth to determine alignment calibration parameters. Alignment calibration can be further refined by driving the host vehicle in a controlled environment following a leading vehicle. Final alignment calibration parameters are authorized and stored in system memory, and applications which use object detection data henceforth adjust the sensor readings according to the calibration parameters. | 11-15-2012 |
20130107669 | VEHICLE LOCALIZATION | 05-02-2013 |
20130138288 | SYSTEM AND METHOD FOR ESTIMATING THE MASS OF A VEHICLE - A vehicle system and method that estimates or approximates the mass of a vehicle so that a more accurate vehicle mass estimate can be made available to other vehicle systems, such as an adaptive cruise control (ACC) system or an automated lane change (LCX) system. In an exemplary embodiment, the method compares an actual acceleration of the vehicle to an expected acceleration while the vehicle is under the control of an automated acceleration event. The difference between these two acceleration values, along with other potential input, may then be used to approximate the actual mass of the vehicle in a way that takes into account items such as passengers, cargo, fuel, etc. Once an accurate vehicle mass estimate is generated, the method may make this estimate available to other vehicle components, devices, modules, systems, etc. so that their performance can be improved. | 05-30-2013 |
20130236047 | ENHANCED DATA ASSOCIATION OF FUSION USING WEIGHTED BAYESIAN FILTERING - A method of associating targets from at least two object detection systems. An initial prior correspondence matrix is generated based on prior target data from a first object detection system and a second object detection system. Targets are identified in a first field-of-view of the first object detection system based on a current time step. Targets are identified in a second field-of-view of the second object detection system based on the current time step. The prior correspondence matrix is adjusted based on respective targets entering and leaving the respective fields-of-view. A posterior correspondence matrix is generated as a function of the adjusted prior correspondence matrix. A correspondence is identified in the posterior correspondence matrix between a respective target of the first object detection system and a respective target of the second object detection system. | 09-12-2013 |
20140032108 | ANCHOR LANE SELECTION METHOD USING NAVIGATION INPUT IN ROAD CHANGE SCENARIOS - A method for selecting an anchor lane for tracking in a vehicle lane tracking system. Digital map data and leading vehicle trajectory data are used to predict lane information ahead of a vehicle. Left and right lane boundary markers are also detected, where available, using a vision system. The lane marker data from the vision system is combined with the lane information from the digital map data and the leading vehicle trajectory data in a lane curvature fusion calculation. The left and right lane marker data from the vision system are also evaluated for conditions such as parallelism and sudden jumps in offsets, while considering the presence of entrance or exit lanes as indicated by the map data. An anchor lane for tracking is selected based on the evaluation of the vision system data, using either the fused curvature calculation or the digital map and leading vehicle trajectory data. | 01-30-2014 |
20140257686 | VEHICLE LANE DETERMINATION - Methods and systems are provided for making lane determinations as to a roadway on which the vehicle is travelling. A determination is made as to a lane of a roadway in which a vehicle is travelling. An identification is made as to an adjacent lane that is adjacent to the lane in which the vehicle is travelling. An assessment is made as to a drivability of the adjacent lane. | 09-11-2014 |
20150081211 | SENSOR-AIDED VEHICLE POSITIONING SYSTEM - A method and system for localizing a vehicle in a digital map includes generating GPS coordinates of the vehicle on the traveled road and retrieving from a database a digital map of a region traveled by the vehicle based on the location of the GPS coordinates. The digital map includes a geographic mapping of a traveled road and registered roadside objects. The registered roadside objects are positionally identified in the digital map by longitudinal and lateral coordinates. Roadside objects in the region traveled are sensed by the vehicle. The sensed roadside objects are identified on the digital map. A vehicle position on the traveled road is determined utilizing coordinates of the sensed roadside objects identified in the digital map. The position of the vehicle is localized in the road as a function of the GPS coordinates and the determined vehicle position utilizing the coordinates of the sensed roadside objects. | 03-19-2015 |