Abstract: A parallel parking assistant system integrated with a vehicle and method thereof are provided, the parking assistant system including a first sensor configured to determine a first distance, a second sensor configured to determine a second distance, and a controller configured to provide commands as a function of the first and second determined distances. The commands include a first command configured to command a steering system to be in a clockwise position while the vehicle is moving in a reverse direction for a first reversing distance, a second command configured to command the steering system to be in a substantially straight position while the vehicle is moving in a reverse direction for a second reversing distance, and a third command configured to command the steering system to be in a counter-clockwise position while the vehicle is a moving in a reverse direction for a third reversing distance.

Abstract: A parallel parking assistant system integrated with a vehicle and method thereof are provided, the parking assistant system including a first sensor configured to determine a first distance, a second sensor configured to determine a second distance, and a controller configured to provide commands as a function of the first and second determined distances. The commands include a first command configured to command a steering system to be in a clockwise position while the vehicle is moving in a reverse direction for a first reversing distance, a second command configured to command the steering system to be in a substantially straight position while the vehicle is moving in a reverse direction for a second reversing distance, and a third command configured to command the steering system to be in a counter-clockwise position while the vehicle is a moving in a reverse direction for a third reversing distance.

Abstract: A parallel parking assistant system integrated with a vehicle and method thereof are provided, the parking assistant system including a first sensor configured to determine a first distance, a second sensor configured to determine a second distance, and a controller configured to provide commands as a function of the first and second determined distances. The commands include a first command configured to command a steering system to be in a clockwise position while the vehicle is moving in a reverse direction for a first reversing distance, a second command configured to command the steering system to be in a substantially straight position while the vehicle is moving in a reverse direction for a second reversing distance, and a third command configured to command the steering system to be in a counter-clockwise position while the vehicle is a moving in a reverse direction for a third reversing distance.

Abstract: A database system and method for obtaining and communicating data is provided, wherein the system includes a plurality of mobile nodes, wherein at least a first mobile node has an environmental data collection device, a location determination device configured to determine a geographical location that is associated with environmental data obtained by the environmental data collection device, and a memory device configured to store the environmental data and the associated geographical location. The first mobile node further includes a processor, and a communication device configured to transmit the environmental data and the associated geographical location to a database, wherein at least one of the database and the processor is configured to categorize the environmental data and the associated geographical location, and communicate data that is a function of the environmental data and the associated geographical location to a second mobile node of the plurality of mobile nodes based upon the categorization.

Abstract: A collision avoidance and warning system and method are provided. The system includes a sensor and a controller. The sensor senses an object in a field of view, wherein the sensor determines a direct range measurement between the sensor and the object and an angle measurement of the object with respect to the sensor. The controller receives the direct range measurement and angle measurement from the sensor, and determines if the object is in an in-path area based upon the direct range measurement and angle measurement, as a function in a pseudo polar coordinate frame.

Abstract: A lane change assist system and method are provided for assisting the driver of the vehicle in maneuvering a lane change. The system includes a range sensor mounted on a vehicle for sensing range to an object in a side detection zone adjacent to one side of the vehicle. The system also includes a controller for determining when the side detection zone is clear for the vehicle to change lanes based on the sensed range signal. The controller determines whether there is sufficient space to initial a lane change maneuver based on the sensed range signal and generates an output signal indicative thereof. An output is provided to warning lights indicative of the determined state for initiating the lane change maneuver.

Abstract: A turning maneuver assist system and method are provided for assisting the driver of a vehicle with a visual image while turning the vehicle. The system includes first and second cameras positioned to generate video images on respective first and second sides of the vehicle. The system also includes a drop-down display located onboard the vehicle for displaying images generated by the first and second video cameras. The system further includes a controller for controlling activation of the first and second cameras and the presentation of images on the display. The controller activates one of the first and second cameras and controls the display to output images captured by the activated camera when the vehicle is determined to be turning. The display is mounted forward and above the driver and moves between a stowed position and a viewable position.

Abstract: A potential collision is predicted by comparing estimates of the time-to-brake (TTB) and the time-to-turn (TTT) of a host vehicle with a computed time-to-collision (TTC). The collision is deemed to be unavoidable when the smaller of TTB and TTT is greater than TTC. The TTT estimate is based in part on the lateral acceleration capability of the vehicle, and the lateral acceleration is initialized to a low value corresponding to its instantaneous capability, and is set incrementally higher than the actual lateral acceleration when the driver initiates evasive turning. The TTT and TTB estimates are increased by the time required to pre-charge the vehicle brakes so that brake pre-charging can be automatically initiated when required to optimize collision mitigation due to braking.

Abstract: An object awareness determination system and method of determining awareness of a driver of a vehicle to an object is provided. The system includes an object monitor including an object detection sensor for sensing an object in a field of view and determining a position of the object. The system also includes an eye gaze monitor including an imaging camera oriented to capture images of the vehicle driver including an eye of the driver. The gaze monitor determines an eye gaze vector. The system further has a controller for determining driver awareness of the object based on the detected object position and the eye gaze vector.

Abstract: A system responds to detection of a vehicle situation by comparing a sensed eye gaze direction of the vehicle operator with data stored in memory. The stored data defines a first predetermined vehicle operator eye gaze direction indicating a high probability of operator desire that an alert signal be given and a second predetermined vehicle operator eye gaze direction indicating a low probability of operator desire that an alert signal be given. On the basis of the comparison, a first or second alert action is selected and an alert apparatus controlled accordingly. For example, the alternative alert actions may include (1) generating an alert signal versus not generating the alert signal, (2) generating an alert signal in a first manner versus generating an alert signal in a second manner, or (3) selecting a first value versus selecting a second value for a parameter in a mathematical control algorithm to determine when or whether to generate an alert signal.

Abstract: An object awareness determination system and method of determining awareness of a driver of a vehicle to an object is provided. The system includes an object monitor including an object detection sensor for sensing an object in a field of view and determining a position of the object. The system also includes an eye gaze monitor including an imaging camera oriented to capture images of the vehicle driver including an eye of the driver. The gaze monitor determines an eye gaze vector. The system further has a controller for determining driver awareness of the object based on the detected object position and the eye gaze vector.

Abstract: A system responds to detection of a vehicle situation by comparing a sensed eye gaze direction of the vehicle operator with data stored in memory. The stored data defines a first predetermined vehicle operator eye gaze direction indicating a high probability of operator desire that an alert signal be given and a second predetermined vehicle operator eye gaze direction indicating a low probability of operator desire that an alert signal be given. On the basis of the comparison, a first or second alert action is selected and an alert apparatus controlled accordingly. For example, the alternative alert actions may include (1) generating an alert signal versus not generating the alert signal, (2) generating an alert signal in a first manner versus generating an alert signal in a second manner, or (3) selecting a first value versus selecting a second value for a parameter in a mathematical control algorithm to determine when or whether to generate an alert signal.

Abstract: A cooperative differential drive system (20) for use in material handling and flight control and guidance systems, and the like. The drive system (20) may be employed in application that require high resolution task repeatability capabilities and the execution of precise position and force trajectory path following routines. A differential gear system (24) is driven by two servo-controlled actuators (22, 23) under control of a controller (21). The first actuator (22) is regulated at constant speed while the second actuator (23) is modulated at an appropriately varying speed to achieve a desired drive speed of a load. The second actuator (23) is controlled such that it dos not change rotational direction. Ultimate control of the load is achieved by way of the differential gear system (24) that combines the two actuator speeds to achieve the desired load speed. The differential gear system (24) is optionally coupled by way of a clutch system (25) to the load.