Abstract: A vehicular vision system includes a camera disposed at and viewing exterior and rearward of a vehicle. The system, as the vehicle is driven forward along a traffic lane of a road, and responsive to processing of image data captured by the camera, determines a traffic lane marker rearward of the vehicle. The system, responsive to determining the traffic lane marker, determines a position of the vehicle within the traffic lane the vehicle is moving along. The system, responsive to determining the position of the vehicle within the traffic lane is within a threshold distance of a side of the traffic lane, alerts an occupant of the vehicle.

Abstract: A vehicular vision system includes a camera disposed at and viewing exterior and rearward of a vehicle. The system, as the vehicle is driven forward along a traffic lane of a road, and responsive to processing of image data captured by the camera, determines a traffic lane marker rearward of the vehicle. The system, responsive to determining the traffic lane marker, determines a position of the vehicle within the traffic lane the vehicle is moving along. The system, responsive to determining the position of the vehicle within the traffic lane is within a threshold distance of a side of the traffic lane, alerts an occupant of the vehicle.

Abstract: A vision system includes a camera viewing at least part of a swing path of a swing, the camera capturing image data. An electronic control unit (ECU) includes an image processor for processing image data captured by the camera to detect presence of objects in the field of view of the camera. The system, responsive to processing by the image processor of image data captured by the camera, and with the swing having an occupant swinging along a swing path of the swing, detects presence of an object that has a potential to collide with the occupant of the swing. The system, responsive to detecting the presence of the object that has the potential to collide with the occupant of the swing, generates an alert and/or engages an arrester to slow the swing as the swing travels along the swing path.

Abstract: A method for testing a sensor of a vehicular sensing system includes displaying, by a processor, a test generation interface on a display screen, and receiving, by the processor, a user input based on a user interacting with the test generation interface. The method includes determining a plurality of parameters based on the user input. The method includes generating a test script based on the parameters that includes at least one test message for performing at least one system test. The method includes transmitting generated test script to a host adapter in communication with the sensor. Responsive to receiving the generated test script, the method includes transmitting, by the host adapter, the test message to the sensor to test the sensor.

Abstract: Systems and apparatuses include a vehicle locator circuit that is structured to receive GPS signal coordinates and a road parameter associated with the GPS signal coordinates. The vehicle locator circuit is further structured to identify a current road segment associated with the GPS coordinates. A map data circuit is structured to store the road parameter and GPS signal coordinates associated with the current road segment. A route response circuit is structured to determine look-ahead parameters characterizing a future road segment based on input received from the vehicle locator circuit and the map data circuit, and a communication interface is structured to communicate the look-ahead parameters to an engine control module for improving vehicle performance during travel on the future road segment.

Abstract: A vehicle may include a controller configured to control the vehicle to operate in an active control mode or a passive control mode. In the passive control mode, the controller may provide a feedback indicator on a human machine interface. In the active control mode, the controller may provide a control command to an engine control unit.

Abstract: A system and method for identifying and analyzing a route using an inexpensive GPS system is provided. The system and method provides a location for storing GPS and vehicle operating data for at least one route, requiring a plurality of runs over the at least one route. Once a predetermined minimum number of runs have been reached, the system and method define a route segment, interpolate additional data points using the GPS and vehicle operating data, synchronize the data over the plurality of runs, and analyze the data. The analyzed data is then provided to a module capable of controlling the operation of an internal combustion engine. The analyzed data is forward-looking in that it permits anticipation of vehicle operation, and more particularly, engine and transmission operation.

Abstract: A vehicle may include a controller configured to control the vehicle to operate in an active control mode or a passive control mode. In the passive control mode, the controller may provide a feedback indicator on a human machine interface. In the active control mode, the controller may provide a control command to an engine control unit.

Abstract: A system and method for identifying and analyzing a route using an inexpensive GPS system is provided. The system and method provides a location for storing GPS and vehicle operating data for at least one route, requiring a plurality of runs over the at least one route. Once a predetermined minimum number of runs have been reached, the system and method define a route segment, interpolate additional data points using the GPS and vehicle operating data, synchronize the data over the plurality of runs, and analyze the data. The analyzed data is then provided to a module capable of controlling the operation of an internal combustion engine. The analyzed data is forward-looking in that it permits anticipation of vehicle operation, and more particularly, engine and transmission operation.