Abstract: An object detection system for a vehicle includes a camera vision module and a Lidar module. The camera vision module includes an imaging device viewing to the exterior of the vehicle and operable to capture image data representative of a scene exterior and forward of the vehicle. The Lidar module includes a Lidar device that, with the Lidar module mounted at a front exterior portion of the vehicle, scans a region forward of the vehicle that overlaps with the field of view of the imaging device. Based at least in part on processing of captured image data by an image processor using vision processing algorithms and based at least in part on distance data provided by the Lidar device, 3-dimensional information relative to the vehicle of an object present exterior of the vehicle is algorithmically constructed.

Abstract: An object detection system for a host vehicle includes an imaging device operable to capture image data representative of a scene exterior the host vehicle. An image processor processes captured image data to detect an object. A ranging device tracks the detected object and determines distance to the detected object. The detected object is assigned a priority score that represents the potential danger of the detected object to the host vehicle. The priority score is at least in part established responsive to image processing by the image processor of captured image data and to distance determined by the ranging unit. The detected object is assigned its priority score based on one of (i) the detected object being a vehicle that is closing with the host vehicle and (ii) the detected object being a pedestrian who is present in the field of view of said imaging device.

Abstract: A driver assistance system for a vehicle includes a camera that, when disposed at the vehicle, views through a windshield of the vehicle. The camera is disposed at a windshield electronics module attached at the windshield of the vehicle. The camera captures image data of a scene forward of the vehicle. A control includes an image processor that processes captured image data. The control, responsive to the image processor processing captured image data, detects an object of interest external to the vehicle. The control utilizes a blockage detection algorithm and, responsive to the image processor processing captured image data, is operable to detect at least a partial blocking condition at the camera.

Abstract: A driver assistance system for a vehicle includes first and second cameras and a rear backup camera. A control processes image data captured by the first camera and determines that the first camera is misaligned when the first camera is disposed at the left side of the vehicle. The control, responsive to a determination of misalignment of the first camera, is operable to algorithmically at least partially compensate for misalignment of the first camera. At least in part responsive to processing of captured image data, a composite image is displayed that provides a view that approximates a view from a single virtual camera. Image data captured at least by the first camera is processed using an edge detection algorithm to detect edges of objects exterior of the vehicle. Responsive at least in part to processing of captured image data, an object of interest exterior of the vehicle is determined.

Abstract: A driver assistance system for a vehicle includes an imaging device disposed at least partially within an exterior rearview mirror assembly of the vehicle. With the exterior rearview mirror assembly attached at a side of the vehicle, the imaging device has a field of view forward of the mirror assembly, rearward of the mirror assembly and sideward of the mirror assembly. A control processes image data captured by the imaging device and is operable to determine that the imaging device is misaligned when the imaging device is disposed at least partially within the exterior rearview mirror assembly at the side of the equipped vehicle. The control, responsive to a determination of misalignment of the imaging device, is operable to at least partially compensate for misalignment of the imaging device by at least one of (i) adjusting processing of captured image data and (ii) adjusting the captured image data.

Abstract: An object detection system for a host vehicle includes an imaging device operable to capture image data representative of a scene exterior the host vehicle. An image processor processes captured image data to detect an object. A ranging device tracks the detected object and determines distance to the detected object. The detected object is assigned a priority score that represents the potential danger of the detected object to the host vehicle. The priority score is at least in part established responsive to image processing by the image processor of captured image data and to distance determined by the ranging unit. The detected object is assigned its priority score based on one of (i) the detected object being a vehicle that is closing with the host vehicle and (ii) the detected object being a pedestrian who is present in the field of view of said imaging device.

Abstract: A driver assistance system for a vehicle includes a camera and a control. The camera is disposed at the vehicle and views forward of the vehicle and is operable to capture image data. The control includes an image processor operable to process image data captured by the camera. The control, responsive at least in part to image data processing by the image processor, is operable to determine when the equipped vehicle is at least one of (i) approaching a construction zone, (ii) entering a construction zone and (iii) driving along a construction zone. The image data processing by the image processor may include at least one of (a) traffic sign recognition, (b) character recognition, (c) object detection, (d) object recognition, (e) spectral discrimination, (f) spatial recognition and (g) lane marker detection.

Abstract: A driver assistance system for a vehicle includes an imaging device disposed at least partially within an exterior rearview mirror assembly of the vehicle. With the exterior rearview mirror assembly attached at a side of the vehicle, the imaging device has a field of view forward of the mirror assembly, rearward of the mirror assembly and sideward of the mirror assembly. A control processes image data captured by the imaging device and is operable to determine that the imaging device is misaligned when the imaging device is disposed at least partially within the exterior rearview mirror assembly at the side of the equipped vehicle. The control, responsive to a determination of misalignment of the imaging device, is operable to at least partially compensate for misalignment of the imaging device by at least one of (i) adjusting processing of captured image data and (ii) adjusting the captured image data.

Abstract: A vehicular imaging system includes an imaging device having a single imaging sensor capturing image data within a field of view. A control within the vehicle includes an image processor and receives image data captured by the single imaging sensor and receives vehicle data via a communication bus of the vehicle. Responsive at least in part to image processing of captured image data, the control detects converging road features along the road the vehicle is travelling and determines a point of intersection where the converging road features would converge. Responsive at least in part to image processing of captured image data, the control automatically corrects for misalignment of the imaging device mounted at the vehicle.

Abstract: A vehicular imaging system comprises a single imaging sensor having a plurality of photosensor elements. The imaging sensor captures image data of a scene exterior of the vehicle within its field of view. Image data captured by the imaging sensor is provided to a control. The control also receives via a communication bus at least one of vehicle pitch information, vehicle yaw information and vehicle steering information. The control detects two substantially straight and converging road features along the road the vehicle is travelling and determines a point of intersection where they would converge using, at least in part, the received vehicle information and the control automatically corrects for misalignment of the imaging sensor mounted at the vehicle.

Abstract: A driver assistance system for a vehicle includes an imaging device disposed at an exterior portion of a vehicle. With the imaging device disposed at the exterior portion of the vehicle, the imaging device has a field of view at least one of rearward of the vehicle and sideward of the vehicle. A control utilizes edge detection in processing image data captured by the imaging device. Responsive at least in part to processing of captured image data by the control, the control determines that an object is present in the field of view of the imaging device. The control is operable to determine that the imaging device is misaligned. The control, responsive to a determination of misalignment of the imaging array sensor, is operable to at least partially compensate for the determined misalignment of the imaging device.

Abstract: An imaging system suitable for use in a vehicle includes an imaging sensor having a two-dimensional array of photosensing pixels that includes at least one sub-array having a first photosensing pixel, a second photosensing pixel, a third photosensing pixel and a fourth photosensing pixel. Spectral filtering is disposed at the photosensing pixels whereby the first photosensing pixel primarily senses red visible light, the second photosensing primarily senses blue visible light, the third photosensing primarily senses green visible light and the fourth photosensing primarily senses infrared radiation. The imaging sensor is disposed at a vehicle and has a field of view external of the vehicle. An image processor is operable for processing image data captured by the imaging sensor. The image data includes outputs of the first, second, third and fourth photosensing pixels. The processing of image data by the image processor may include de-mosaicing that reduces infrared color wash-out.

Abstract: A driver assistance system for a vehicle includes a camera disposed at and viewing forwardly through a windshield of the equipped vehicle and operable to capture image data. A control operable to process captured image data utilizing algorithmic decision-making, which uses an edge detection algorithm. The control is operable to process captured image data to detect a pedestrian present in the field of view of the camera. The control is operable to process captured image data to detect an oncoming headlight or a leading taillight of another vehicle ahead of the equipped vehicle. Responsive to pedestrian detection, the control is operable to generate an alert to a driver of the equipped vehicle. Responsive to detection of an oncoming headlight or a leading taillight of another vehicle ahead of the equipped vehicle, a light beam of a headlight of the equipped vehicle is adjusted.

Abstract: An imaging system for a vehicle includes an imaging sensor having four photosensing pixels of a sub-array, with one of (a) a red-light transmitting spectral filter disposed at a first photosensing pixel whereby the first pixel of each sub-array primarily senses red visible light and with an IR transmitting spectral filter disposed at the fourth photosensing pixel whereby the fourth pixel of each sub-array primarily senses infrared radiation, and (b) a red-light transmitting spectral filter disposed at a first photosensing pixel whereby the first pixel of each sub-array primarily senses red visible light and with an IR transmitting spectral filter disposed at a third photosensing pixel whereby the third pixel of each sub-array primarily senses infrared radiation. An image processor processes the output of each sub-array to determine at least one of an infrared component of the imaged scene and a visible light component of the imaged scene.

Abstract: A driver assistance system includes a stereo vision system that includes at least one camera and at least one sensor disposed on or in a vehicle; a roadside marker detection unit configured to receive stereo image data from the stereo vision system, and to detect roadside markers from the stereo image data; and a road path estimation unit configured to estimate a road path in a direction of travel of the vehicle, based on the roadside markers detected by the roadside marker detection unit.

Abstract: A vehicular vision system includes an imaging device and a control operable to process image data captured by the imaging device. The control is operable to process the captured image data to detect at least one of (i) a sign ahead of the equipped vehicle, (ii) an animal ahead of the equipped vehicle and (iii) a pedestrian ahead of the equipped vehicle. The control is operable to process the captured image data to detect an oncoming headlight or a leading taillight of another vehicle ahead of the equipped vehicle. An illumination source is operable to illuminate generally forwardly and/or generally sidewardly of the equipped vehicle, and wherein illumination emanating from the illumination source is adjustable.

Abstract: An object detection system for a host vehicle includes an imaging device, a ranging device and a processor. The imaging device has a field of view exterior of the host vehicle and is operable to capture image data representative of an object exterior the host vehicle. The ranging device has a field of view that sweeps at least the field of view of the imaging device and that detects the object exterior the host vehicle. The processor processes image data from the imaging device and processes data from the ranging device in order to determine if the detected object is an object of interest. The determination that the detected object is an object of interest is made in accordance with a priority score.

Abstract: An imaging system for a vehicle includes an imaging sensor and a video display device. The imaging system generates an overlay that is electronically superimposed on the displayed images to assist a driver of the vehicle when executing a backup maneuver. The overlay has first, second and third overlay zones, with the overlay zones indicative of respective distance ranges from the rear of the vehicle to respective distances. As indicated to the driver viewing the video display screen when executing a backup maneuver, the first distance is closer to the rear of the vehicle than the second distance and the second distance is closer to the rear of the vehicle than the third distance. The first overlay zone may be a first color and the second overlay zone may be a second color and the third overlay zone may be a third color.

Abstract: A driver assistance system for a vehicle includes an imaging device disposed at an exterior portion of a vehicle. With the imaging device disposed at the exterior portion of the vehicle, the imaging device has a field of view at least one of rearward of the vehicle and sideward of the vehicle. A control utilizes edge detection in processing image data captured by the imaging device. Responsive at least in part to processing of captured image data by the control, the control determines that an object is present in the field of view of the imaging device. The control is operable to determine that the imaging device is misaligned. The control, responsive to a determination of misalignment of the imaging array sensor, is operable to at least partially compensate for the determined misalignment of the imaging device.

Abstract: An imaging system for a vehicle includes an imaging sensor having four photosensing pixels of a sub-array, with one of (a) a red-light transmitting spectral filter disposed at a first photosensing pixel whereby the first pixel of each sub-array primarily senses red visible light and with an IR transmitting spectral filter disposed at the fourth photosensing pixel whereby the fourth pixel of each sub-array primarily senses infrared radiation, and (b) a red-light transmitting spectral filter disposed at a first photosensing pixel whereby the first pixel of each sub-array primarily senses red visible light and with an IR transmitting spectral filter disposed at a third photosensing pixel whereby the third pixel of each sub-array primarily senses infrared radiation. An image processor processes the output of each sub-array to determine at least one of an infrared component of the imaged scene and a visible light component of the imaged scene.