Abstract: A vehicular control system includes a forward-viewing camera, a forward-sensing sensor and an in-cabin-sensing sensor. With the system controlling driving of the vehicle, the system determines a triggering event that triggers handing over driving of the vehicle to a driver of the vehicle before the vehicle encounters an event point associated with the triggering event. The vehicular control system (i) determines a total action time available before the vehicle encounters the event point, (ii) estimates a driver takeover time for the driver to take over control of the vehicle and (iii) estimates a handling time for the driver to control the vehicle to avoid encountering the event point. Responsive to the vehicular control system determining that the estimated driver takeover time is less than the difference between the determined total action time and the estimated handling time, control of the vehicle is handed over to the driver of the vehicle.

Abstract: A vehicular control system includes at least one processor that processes image data captured by a forward viewing camera and radar data captured by a forward sensing radar sensor. With the system controlling driving of the vehicle, the system determines a triggering event that requires driving of the vehicle to be handed over to a driver of the vehicle before the vehicle encounters an event point, and the system (i) determines a total action time until the vehicle encounters the event, (ii) estimates a driver take over time for the driver to take over control and (iii) estimates a handling time for the driver to control the vehicle to avoid encountering the event point. Based on the determined and estimated times, the system (i) requests the driver take over control of the vehicle or (ii) controls the vehicle to slow down and stop the vehicle before the event point.

Abstract: A method for displaying video images via a vehicular vision system includes providing a rear backup camera having an imager and a wide angle lens disposed at the imager with its center axis vertically offset from a center region of an imaging array sensor of the imager. A distant central horizon region is imaged at the upper region of the imaging array sensor via light that has passed through a center region of the wide angle lens, and a closer region is imaged at the center region and the lower region of the imaging array sensor via light that has passed through a lower peripheral region of the wide angle lens. Video images derived from image data captured by the rear backup camera are displayed on a video display for viewing by a driver of the vehicle during a reversing maneuver of the vehicle.

Abstract: A vehicular automated parking system includes a plurality of cameras viewing exterior of the vehicle. While the vehicle is traveling along the road, the vehicular automated parking system operates in a parking space locating mode to determine available parking spaces at least in part via processing, at an electronic control unit having an image processor, of image data captured by at least one camera of the plurality of cameras. The vehicular automated parking system fuses the determined available parking spaces with map data to generate an annotated map for display at the video display screen for viewing by the driver of the vehicle to assist the driver in selecting a parking space from the determined available parking spaces. After selection of the parking space, the vehicular automated parking system parks the equipped vehicle in the selected parking space.

Abstract: A vehicular automated parking system includes a camera having a field of view rearward of the vehicle. When the vehicle is parked in a parking space, with a forward vehicle parked in front of the vehicle and a rearward vehicle parked behind the vehicle, the vehicular automated parking system determines a forward limit of the parking space responsive to a driver of the vehicle driving the vehicle forward until a front end of the vehicle is close to the forward vehicle. Responsive to the determined forward limit of the parking space, and responsive to processing by an image processor of image data captured by the camera, the vehicular automated parking system controls the vehicle when the vehicle is leaving the parking space in a manner that avoids the forward vehicle parked in front of the vehicle and the rearward vehicle parked behind the vehicle.

Abstract: A vehicular control system includes at least one processor that processes image data captured by a forward viewing camera and radar data captured by a forward sensing radar sensor. With the system controlling driving of the vehicle, the system determines a triggering event that requires driving of the vehicle to be handed over to a driver of the vehicle before the vehicle encounters an event point, and the system (i) determines a total action time until the vehicle encounters the event, (ii) estimates a driver take over time for the driver to take over control and (iii) estimates a handling time for the driver to control the vehicle to avoid encountering the event point. Based on the determined and estimated times, the system (i) requests the driver take over control of the vehicle or (ii) controls the vehicle to slow down and stop the vehicle before the event point.

Abstract: A vehicular control system includes a control having a processor that processes image data captured by a forward viewing camera. When the control system is controlling driving of the vehicle, the control determines a triggering event that requires driving of the vehicle to be handed over to a driver of the vehicle before the vehicle encounters an event point. Responsive to determination of the triggering event, the control (i) determines a total action time until the vehicle encounters the event, (ii) estimates a driver take over time for the driver to take over control and (iii) estimates a handling time for the vehicle to be controlled to avoid encountering the event point, and, responsive to the determination and estimations, the control system (i) allows the driver to take over control of the vehicle or (ii) controls the vehicle to slow down and stop the vehicle before the event point.

Abstract: A method for displaying video images via a vehicular vision system includes providing a rear backup camera having an imager and a wide angle lens disposed at the imager with its center axis vertically offset from a center region of an imaging array sensor of the imager. A distant central horizon region is imaged at the upper region of the imaging array sensor via light that has passed through a center region of the wide angle lens, and a closer region is imaged at the center region and the lower region of the imaging array sensor via light that has passed through a lower peripheral region of the wide angle lens. Video images derived from image data captured by the rear backup camera are displayed on a video display for viewing by a driver of the vehicle during a reversing maneuver of the vehicle.

Abstract: A vision system for a vehicle includes a rear backup camera that is operable to capture image data. The rear backup camera is configured to be disposed at the vehicle so as to have a rearward field of view. The rear backup camera has an imager and a wide angle lens, which is disposed at the imager with its center axis offset from a center region of the imager so as to be disposed at and to image at an upper region of the imager. A distant central horizon region is imaged at the upper region of the imager and a closer region is imaged at the center region and the lower region of the imager. Video images derived from image data captured by the rear backup camera are displayed on a video display for viewing by a driver of the vehicle during the reversing maneuver of the vehicle.

Abstract: A vision system for a vehicle includes a rear backup camera that is operable to capture image data. The rear backup camera is configured to be disposed at the vehicle so as to have a rearward field of view. The rear backup camera has an imager and a wide angle lens, which is disposed at the imager with its center axis offset from a center region of the imager so as to be disposed at and to image at an upper region of the imager. A distant central horizon region is imaged at the upper region of the imager and a closer region is imaged at the center region and the lower region of the imager. Video images derived from image data captured by the rear backup camera are displayed on a video display for viewing by a driver of the vehicle during the reversing maneuver of the vehicle.

Abstract: A vehicular control system includes a control having a processor that processes image data captured by a forward viewing camera. When the control system is controlling driving of the vehicle, the control determines a triggering event that requires driving of the vehicle to be handed over to a driver of the vehicle before the vehicle encounters an event point. Responsive to determination of the triggering event, the control (i) determines a total action time until the vehicle encounters the event, (ii) estimates a driver take over time for the driver to take over control and (iii) estimates a handling time for the vehicle to be controlled to avoid encountering the event point, and, responsive to the determination and estimations, the control system (i) allows the driver to take over control of the vehicle or (ii) controls the vehicle to slow down and stop the vehicle before the event point.

Abstract: A vision system for a vehicle includes side and rear cameras that are operable to capture image data. The rear camera is configured to be disposed at a rear portion of the vehicle so as to have a rearward field of view and the side cameras are configured to be disposed at respective side portions of the vehicle so as to have respective sideward and rearward fields of view. The rear camera has a rear imager and a wide angle lens, which is disposed at the rear imager with its center axis offset from a center region of the rear imager so as to be disposed at and to image at an upper region of the rear imager. An image processor processes captured image data to merge captured image data to provide a panoramic image for display to the driver during a reversing maneuver of the vehicle.

Abstract: A control system that is operable to control a vehicle in an autonomous or semi-autonomous mode includes a processor that processes data captured by a plurality of exterior sensing sensors. When the control system is operating in the autonomous or semi-autonomous mode and responsive to a determination of an upcoming event that requires the system to hand over control of the vehicle to a driver before the vehicle encounters the event, the control determines (i) a total action time until the vehicle encounters the event, (ii) an estimated time for the driver to take over control and (iii) an estimated handling time for the vehicle to be controlled before the vehicle encounters the event. Responsive to the determinations, the control system (i) allows the driver to take over control of the vehicle or (ii) controls the vehicle to slow down and stop the vehicle before the vehicle encounters the event.

Abstract: A vehicular automated parking system includes a camera having a field of view rearward of the vehicle. When the vehicle is parked in a parking space, with a forward vehicle parked in front of the vehicle and a rearward vehicle parked behind the vehicle, the vehicular automated parking system determines a forward limit of the parking space responsive to a driver of the vehicle driving the vehicle forward until a front end of the vehicle is close to the forward vehicle. Responsive to the determined forward limit of the parking space, and responsive to processing by an image processor of image data captured by the camera, the vehicular automated parking system controls the vehicle when the vehicle is leaving the parking space in a manner that avoids the forward vehicle parked in front of the vehicle and the rearward vehicle parked behind the vehicle.

Abstract: A driver assistance system of a vehicle includes at least one vehicle environmental sensor having a field of sensing exterior of the vehicle. A sensor data processor is operable to process sensor data captured by the sensor. When the vehicle is operated, the sensor data processor receives captured sensor data that is representative of the vehicle surrounding scene. The sensor data processor fuses the sensor data with map data to generate an annotated master map of the scene captured by the sensor. A display device is operable to display information for viewing by a driver of the vehicle. The displayed information is derived at least in part from the annotated master map and is displayed for viewing by the driver of the vehicle who is executing a maneuver of the vehicle.

Abstract: A control system that is operable to control a vehicle in an autonomous or semi-autonomous mode includes a processor that processes data captured by a plurality of exterior sensing sensors. When the control system is operating in the autonomous or semi-autonomous mode and responsive to a determination of an upcoming event that requires the system to hand over control of the vehicle to a driver before the vehicle encounters the event, the control determines (i) a total action time until the vehicle encounters the event, (ii) an estimated time for the driver to take over control and (iii) an estimated handling time for the vehicle to be controlled before the vehicle encounters the event. Responsive to the determinations, the control system (i) allows the driver to take over control of the vehicle or (ii) controls the vehicle to slow down and stop the vehicle before the vehicle encounters the event.

Abstract: A vision system for a vehicle includes side and rear cameras that are operable to capture image data. The rear camera is configured to be disposed at a rear portion of the vehicle so as to have a rearward field of view and the side cameras are configured to be disposed at respective side portions of the vehicle so as to have respective sideward and rearward fields of view. The rear camera has a rear imager and a wide angle lens, which is disposed at the rear imager with its center axis offset from a center region of the rear imager so as to be disposed at and to image at an upper region of the rear imager. An image processor processes captured image data to merge captured image data to provide a panoramic image for display to the driver during a reversing maneuver of the vehicle.

Abstract: A driver assistance system of a vehicle includes at least one vehicle environmental sensor having a field of sensing exterior of the vehicle. A sensor data processor is operable to process sensor data captured by the sensor. When the vehicle is operated, the sensor data processor receives captured sensor data that is representative of the vehicle surrounding scene. The sensor data processor fuses the sensor data with map data to generate an annotated master map of the scene captured by the sensor. A display device is operable to display information for viewing by a driver of the vehicle. The displayed information is derived at least in part from the annotated master map and is displayed for viewing by the driver of the vehicle who is executing a maneuver of the vehicle.

Abstract: The invention relates to a lifting device for raising the hood (20) of a motor vehicle during a collision with a pedestrian. The device comprises a retaining member (10) for connecting the hood (20) to the vehicle bodywork (14) and a pyrotechnic explosive unit (16) for detaching the retaining member (10). To guarantee a reliable operation, the device is equipped with lifting means (18) for raising the hood (20) into a collision position, the means being actuated by the energy of the explosive unit (16) released during the detachment of the retaining member (10).

Abstract: The invention relates to a lifting device for raising the hood (20) of a motor vehicle during a collision with a pedestrian. The device comprises a retaining member (10) for connecting the hood (20) to the vehicle bodywork (14) and a pyrotechnic explosive unit (16) for detaching the retaining member (10). To guarantee a reliable operation, the device is equipped with lifting means (18) for raising the hood (20) into a collision position, the means being actuated by the energy of the explosive unit (16) released during the detachment of the retaining member (10).