Abstract: A method of verifying the health and functionality of at least one vehicle sensor is disclosed herein. The method includes positioning the vehicle within a controlled environment test facility, displaying a predetermined test pattern to the at least one vehicle sensor as the vehicle travels within the controlled environment test facility, receiving sensor data corresponding to a performance condition of the at least one sensor from the at least one vehicle sensor, transmitting the sensor data to a remote processor, and determining a functional condition of the at least one vehicle sensor based on the sensor data.

Abstract: A method and system for autonomously navigating a vehicle toward a passenger route endpoint using a telematics unit installed in the vehicle. The method carried out by the system includes the steps of determining that the vehicle is approaching the passenger route endpoint and remotely navigating the vehicle by identifying a passenger endpoint location near the passenger route endpoint using at least a remote facility separate from the vehicle. The passenger endpoint location may be determined from at least a current or real-time status of a passenger endpoint condition at the passenger route endpoint.

Abstract: A method of calculating at least one dimension of a towed vehicle includes sensing an image of the towed vehicle with an image sensing device. A feature on the towed vehicle in the sensed image of the towed vehicle is identified with a controller using a dimension determination algorithm. The dimension of the towed vehicle is determined from the identified feature of the towed vehicle, with the controller using the dimension determination algorithm. The dimension of the towed vehicle may be input into a vehicle tow controller, to enable the vehicle tow controller to control the tow vehicle.

Abstract: A spray nozzle system includes a housing having an upper cap, a neck portion for helping to support the housing adjacent a component, and at least one fluid flow line for supplying a fluid to an interior area of the housing. A plurality of spray nozzles may be included which are housed in the housing and in communication with the at least one fluid line for distributing the fluid over a circumferential surface of the component.

Abstract: Systems are provided for mounting a sensor to a vehicle. In one embodiment, a sensor mounting system includes a mounting assembly coupled to a body of the vehicle. The mounting assembly has a first mounting plate spaced apart from a second mounting plate by at least one isolation member. The second mounting plate is coupled to the body of the vehicle. The sensor mounting system also includes a turret housing coupled to the first mounting plate so as to be movable relative to the first mounting plate. The turret housing defines at least one receptacle for a first sensing device.

Abstract: Methods are provided for intelligently overriding a driving automation system for a vehicle. The method first identifies a road feature ahead of the vehicle that requires overriding the engaged driving automation system. A deceleration zone is calculated for the vehicle prior to reaching the road feature and a transition zone is identified for the vehicle to pass through while under driver control. The driver is signaled to disengage the driving automation system as the vehicle approaches the deceleration zone and take control of the vehicle. If the driver fails to take control, the vehicle stops and shuts off the driving automation system. If the driver takes control, the vehicle passes through the transition zone and the driving automation system re-engages once the vehicle exits the transition zone.

Abstract: A method of verifying the health and functionality of at least one vehicle sensor is disclosed herein. The method includes positioning the vehicle within a controlled environment test facility, displaying a predetermined test pattern to the at least one vehicle sensor as the vehicle travels within the controlled environment test facility, receiving sensor data corresponding to a performance condition of the at least one sensor from the at least one vehicle sensor, transmitting the sensor data to a remote processor, and determining a functional condition of the at least one vehicle sensor based on the sensor data.

Abstract: Systems are provided for mounting a sensor to a vehicle. In one embodiment, a sensor mounting system includes a mounting assembly coupled to a body of the vehicle. The mounting assembly has a first mounting plate spaced apart from a second mounting plate by at least one isolation member. The second mounting plate is coupled to the body of the vehicle. The sensor mounting system also includes a turret housing coupled to the first mounting plate so as to be movable relative to the first mounting plate. The turret housing defines at least one receptacle for a first sensing device.

Abstract: A spray nozzle system includes a housing having an upper cap, a neck portion for helping to support the housing adjacent a component, and at least one fluid flow line for supplying a fluid to an interior area of the housing. A plurality of spray nozzles may be included which are housed in the housing and in communication with the at least one fluid line for distributing the fluid over a circumferential surface of the component.

Abstract: A method for localizing a vehicle in a digital map. GPS raw measurement data is retrieved from satellites. A digital map of a region traveled by the vehicle based on the raw measurement data is retrieved from a database. 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 earth-fixed coordinates. Roadside objects are sensed in the region traveled by the vehicle using distance data and bearing angle data. The sensed roadside objects are matched on the digital map. A vehicle position is determined on the traveled road by fusing raw measurement data and sensor measurements of the identified roadside objects. The position of the vehicle is represented as a function of linearizing raw measurement data and the sensor measurement data as derived by a Jacobian matrix and normalized measurements, respectively.

Abstract: A method and apparatus for detecting a vehicle hazard are provided. The method includes: detecting a second vehicle based on information received from at least one sensor of a first vehicle; determining whether the second vehicle presents a hazard based on the information received from the at least one sensor of the first vehicle; and transmitting a notification alerting of the second vehicle if it is determined that the second vehicle presents a hazard.

Abstract: A system for generating mapping data includes a host vehicle and at least one sensor coupled to the host vehicle. The sensor is capable of detecting a traffic control device and capable of detecting motion of a vehicle. The system additionally includes non-transient data storage and a processor. The processor is in communication with the sensor and the data storage. The processor is configured to, in response to the at least one sensor detecting a traffic control device and detecting motion of a vehicle during a drive cycle, identify a lane of traffic associated with the vehicle, associate the lane of traffic with the traffic control device, and store the association of the lane of traffic with the traffic control device in the data storage for subsequent access by an automated driving system.

Abstract: A system for generating mapping data includes a host vehicle and at least one sensor coupled to the host vehicle. The sensor is capable of detecting a traffic control device and capable of detecting motion of a vehicle. The system additionally includes non-transient data storage and a processor. The processor is in communication with the sensor and the data storage. The processor is configured to, in response to the at least one sensor detecting a traffic control device and detecting motion of a vehicle during a drive cycle, identify a lane of traffic associated with the vehicle, associate the lane of traffic with the traffic control device, and store the association of the lane of traffic with the traffic control device in the data storage for subsequent access by an automated driving system.

Abstract: A system and method for selectively reducing or filtering data provided by one or more vehicle mounted sensors before using that data to detect, track and/or estimate a stationary object located along the side of a road, such as a guardrail or barrier. According to one example, the method reduces the amount of data by consolidating, classifying and pre-sorting data points from several forward looking radar sensors before using those data points to determine if a stationary roadside object is present. If the method determines that a stationary roadside object is present, then the reduced or filtered data points can be applied to a data fitting algorithm in order to estimate the size, shape and/or other parameters of the object. In one example, the output of the present method is provided to automated or autonomous driving systems.

Abstract: A method of calculating at least one dimension of a towed vehicle includes sensing an image of the towed vehicle with an image sensing device. A feature on the towed vehicle in the sensed image of the towed vehicle is identified with a controller using a dimension determination algorithm. The dimension of the towed vehicle is determined from the identified feature of the towed vehicle, with the controller using the dimension determination algorithm. The dimension of the towed vehicle may be input into a vehicle tow controller, to enable the vehicle tow controller to control the tow vehicle.

Abstract: An apparatus for generating and displaying a projected digital image includes an actuator, a holographic encoded medium with a holographic pattern, a light source, and a controller. The holographic encoded medium is disposed in operable communication with the actuator. The light source is configured to produce a coherent light disposed in optical communication with the holographic encoded medium. The controller is operable to control synchronization of the coherent light from the light source with a position of the holographic encoded medium as driven by the actuator to produce the projected digital image on a projection surface based on directing the coherent light to different portions of the holographic pattern at different times.

Abstract: A method is disclosed for improved target grouping of sensor measurements in an object detection system. The method uses road curvature information to improve grouping accuracy by better predicting a new location of a known target object and matching it to sensor measurements. Additional target attributes are also used for improved grouping accuracy, where the attributes includes range rate, target cross-section and others. Distance compression is also employed for improved grouping accuracy, where range is compressed in a log scale calculation in order to diminish errors in measurement of distant objects. Grid-based techniques include the use of hash tables and a flood fill algorithm for improved computational performance of target object identification, where the number of computations can be reduced by an order of magnitude.

Abstract: A method for localizing a vehicle in a digital map. GPS raw measurement data is retrieved from satellites. A digital map of a region traveled by the vehicle based on the raw measurement data is retrieved from a database. 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 earth-fixed coordinates. Roadside objects are sensed in the region traveled by the vehicle using distance data and bearing angle data. The sensed roadside objects are matched on the digital map. A vehicle position is determined on the traveled road by fusing raw measurement data and sensor measurements of the identified roadside objects. The position of the vehicle is represented as a function of linearizing raw measurement data and the sensor measurement data as derived by a Jacobian matrix and normalized measurements, respectively.

Abstract: Methods, systems, and vehicles are provided for localizing a vehicle. A sensor is configured to detect an object disposed in a generally upward direction from the vehicle while the vehicle is travelling. A processor is coupled to the sensor. The processor is configured to correlate the object with information from a map database, thereby generating a correlation, and determine a geographic location of the vehicle based on the correlation.

Abstract: 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.