Abstract: A method and system may manage the driver's attention while driving. The driver may be driving using an autonomous driving system or limited-ability autonomous driving system. A method may detect, by a sensor, characteristics of a driver; determine, based on the detected characteristics of the driver, whether the driver exercises sufficient supervisory control of the vehicle; and provide a series of one or more prompts, wherein each prompt's intrusiveness is related to the determination of whether the driver exercises sufficient supervisory control of the vehicle.

Abstract: Methods and systems for controlling a driving feature for an automated driving system are provided. In one embodiment, a method includes: receiving a first sensor signal from a first sensor; receiving a second sensor signal from a second sensor; selectively determining a driver intent based on at least one of the first sensor signal and the second sensor signal; and controlling the driving feature based on the driver intent.

Abstract: A method of detecting and tracking objects using multiple radar sensors. Objects relative to a host vehicle are detected from radar data generated by a sensing device. The radar data includes Doppler measurement data. Clusters are formed, by a processor, as a function of the radar data. Each cluster represents a respective object. Each respective object is classified, by the processor, as stationary or non-stationary based on the Doppler measurement data of each object and a vehicle speed of the host vehicle. Target tracking is applied, by the processor, on an object using Doppler measurement data over time in response to the object classified as a non-stationary object; otherwise, updating an occupancy grid in response to classifying the object as a stationary object.

Abstract: An augmented reality system includes a vision output device for displaying virtual images. A sensing device captures an image within a reference frame. The vision output device is captured within the image. A processing unit identifies the vision output device within the reference frame of the captured image and localizes the vision output device within the reference frame of the captured image for identifying an absolute position and orientation of the vision output device within the reference frame of the captured image. The vision output device generates virtual displays to a user at respective locations based on the absolute position and orientation of the vision output device within reference frame of the captured image. The sensing device captures a user's selection of a virtual control. The processing unit identifies the selection of the virtual control within the captured image and enables a control action of a controllable device.

Abstract: A method and system may manage the driver's attention while driving. The driver may be driving using an autonomous driving system or limited-ability autonomous driving system. A steering wheel device may indicate to the driver a level of required supervisory control of a vehicle. The steering wheel device may include indicators to flash lights, vibrate, or provide other indicators. The indicators may have distinct levels of intensity for each level of supervisory control required to safely control a vehicle.

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.

Abstract: A method and system for driver attention management system may include means for closed-loop diagnostics. A convenience message may alert a driver of an item of interest to the driver. A sensor may detect the driver's response to the convenience message. Based on the response to the convenience message, the characteristics of an attentive response from the driver may be determined. The determined attentive response may be used by a driver attention management system. The driver attention management system may be able to diagnose errors in the sensors that are used in the driver attention management system. The driver attention management system may also be able to determine whether a driver is exercising sufficient supervisory control of a vehicle by determining whether the driver is attentively responding to prompts provided by the driver attention management system. The driver attention management system may be used in an autonomous or semi-autonomous driving system.

Abstract: A method to selectively prevent a vehicle from resuming a vehicle set speed stored in memory of a cruise control system includes monitoring a vehicle speed, determining that the vehicle speed indicates operation in a low speed range, determining a threshold slow zone maneuver based upon the vehicle speed substantially remaining in the low speed range through a predetermined duration, and inhibiting resumption of the vehicle set speed based upon the threshold slow zone maneuver.

Abstract: Methods and control systems are provided for automatically controlling operation of a vehicle. In one embodiment, the control system includes an exterior sensor for sensing the environment outside the vehicle. A processor is in communication with the exterior sensor and configured to calculate a driving plan of the vehicle based at least partially on the sensed environment outside the vehicle. The processor is also configured to calculate a confidence level of the driving plan of the vehicle based at least partially on the sensed environment around the vehicle. The control system also includes a display in communication with the processor and configured to receive data from the processor and display a representation of at least one of the driving plan and the confidence level.

Abstract: A method and system for driver attention management system may include means for closed-loop diagnostics. A convenience message may alert a driver of an item of interest to the driver. A sensor may detect the driver's response to the convenience message. Based on the response to the convenience message, the characteristics of an attentive response from the driver may be determined. The determined attentive response may be used by a driver attention management system. The driver attention management system may be able to diagnose errors in the sensors that are used in the driver attention management system. The driver attention management system may also be able to determine whether a driver is exercising sufficient supervisory control of a vehicle by determining whether the driver is attentively responding to prompts provided by the driver attention management system. The driver attention management system may be used in an autonomous or semi-autonomous driving system.

Abstract: An augmented reality system includes a vision output device for displaying virtual images. A sensing device captures an image within a reference frame. The vision output device is captured within the image. A processing unit identifies the vision output device within the reference frame of the captured image and localizes the vision output device within the reference frame of the captured image for identifying an absolute position and orientation of the vision output device within the reference frame of the captured image. The vision output device generates virtual displays to a user at respective locations based on the absolute position and orientation of the vision output device within reference frame of the captured image. The sensing device captures a user's selection of a virtual control. The processing unit identifies the selection of the virtual control within the captured image and enables a control action of a controllable device.

Abstract: A vehicle system for providing an interface for driver control of at least a partially autonomous vehicle. The system includes a driver command processor that receives request signals from a driver interface device of the driver's desire for the vehicle system to take certain actions and sends appropriate signals in response thereto to the proper autonomous vehicle systems. The driver command processor also sends signal to a display device indicating available actions, acknowledgement of the driver request, status of actions being taken or to be taken, etc.

Abstract: A vehicle lateral control system includes a lane marker module configured to determine a heading and displacement of a vehicle in response to images received from a secondary sensing device, a lane information fusion module configured to generate vehicle and lane information in response to data received from heterogeneous vehicle sensors and a lane controller configured to generate a collision free vehicle path in response to the vehicle and lane information from the lane information fusion module and an object map.

Abstract: A vehicle is configured to execute an autonomic lane change maneuver and is equipped with a spatial monitoring system. Each of a plurality of objects located proximate to the vehicle is monitored. Locations of each of the objects are predicted relative to a projected trajectory of the vehicle. A collision risk level between the vehicle and each of the objects is assessed.

Abstract: A method to selectively prevent a vehicle from resuming a vehicle set speed stored in memory of a cruise control system includes monitoring a vehicle speed, determining that the vehicle speed indicates operation in a low speed range, determining a threshold slow zone maneuver based upon the vehicle speed substantially remaining in the low speed range through a predetermined duration, and inhibiting resumption of the vehicle set speed based upon the threshold slow zone maneuver.

Abstract: A vehicle is configured to execute an autonomic lane change maneuver and is equipped with a spatial monitoring system. Each of a plurality of objects located proximate to the vehicle is monitored. Locations of each of the objects are predicted relative to a projected trajectory of the vehicle. A collision risk level between the vehicle and each of the objects is assessed.

Abstract: A vehicle system for providing an interface for driver control of at least a partially autonomous vehicle. The system includes a driver command processor that receives request signals from a driver interface device of the driver's desire for the vehicle system to take certain actions and sends appropriate signals in response thereto to the proper autonomous vehicle systems. The driver command processor also sends signal to a display device indicating available actions, acknowledgement of the driver request, status of actions being taken or to be taken, etc.

Abstract: A rear cross-traffic collision avoidance system that provides a certain action, such as a driver alert or automatic braking, in the event of a collision threat from cross-traffic. The system includes object detection sensors for detecting objects in the cross-traffic and vehicle sensors for detecting the vehicle turning. A controller uses the signals from the object detection sensors and the vehicle sensors to determine and identify object tracks that may interfere with the subject vehicle based on the vehicle turning.

Abstract: A system for evaluating the optical characteristics of curved surfaces includes a light source disposed to scan a beam of light across a surface and ranging means for measuring the distance from the light source to the point being scanned and a controller for controlling the position of the light beam with regard to the measured distance so as to maintain reflected illumination upon a detector. By analysis of the profile of the reflected light, parameters such as gloss, distinctness of image, orange peel and surface roughness may be readily determined.

Abstract: A three-dimensional triangulation-type sensor-illumination system adapted for connection to a machine vision computer. The illumination source in the preferred system comprises a unique cross hair light pattern which provides sufficient image data to the computer to enable the computer to make three-dimensional measurements of a wide variety of features, including edges, corners, holes, studs, designated portions of a surface and intersections of surfaces. The illumination source and sensor are both mounted within a single housing in a specific position and orientation relative to one another, thereby permitting the system to be internally calibrated. In addition, the sensor-illuminator unit is preferably mounted in a test fixture so that the light source is substantially normal to the surface of the part to be examined and the sensor is thereby positioned at a perspective angle relative thereto.