Abstract: A vehicular control system includes a camera and a receiver disposed at the equipped vehicle. A control includes an image processor that processes image data captured by the camera to detect vehicles present within the field of view of the camera. The vehicular control system determines presence of another vehicle that constitutes a potential hazard existing exterior of the equipped vehicle responsive at least in part to a wireless communication originating from the other vehicle and received by the receiver. When the other vehicle enters the field of view of the camera, and responsive at least in part to the image processor processing image data captured by the camera, the control detects that the other vehicle is present within the field of view of the camera and controls at least one vehicle function of the equipped vehicle to mitigate collision with the other vehicle.

Abstract: A driver assist system for a vehicle includes a camera, a receiver and a control. The camera has a field of view exterior of the vehicle and is operable to capture image data. The receiver is operable to receive a wireless communication from a communication device disposed at another vehicle. The control includes a data processor that processes captured image data to detect objects. The wireless communication includes a car-to-car communication. The driver assist system, responsive at least in part to processing by the data processor of captured image data and to the wireless communication received by the receiver, determines a potential hazard existing in a forward path of travel of the equipped vehicle. The control, responsive at least in part to such determination, controls at least one vehicle function of the equipped vehicle to mitigate the potential hazard in the forward path of travel of the equipped vehicle.

Abstract: A vehicular control system for a vehicle includes a plurality of sensors. Responsive to data processing, the vehicular control system is operable to determine respective speeds of the determined vehicles and respective directions of travel of the determined vehicles, and determines respective influence values for the determined vehicles based on a determined potential hazard to the equipped vehicle presented by the determined vehicles. A plurality of paths for the equipped vehicle is determined, and the determined plurality of paths is assessed by a decision algorithm that ranks each of the determined paths based on likelihood of collision of the equipped vehicle along a respective determined path with one or more determined vehicles. A path of travel is selected from the plurality of determined paths responsive at least in part to the rankings of the paths and to the determined types of vehicles along one or more of the determined paths.

Abstract: A vision system for a vehicle includes a plurality of cameras and a processor operable to process image data captured by the cameras to generate images derived from image data captured by at least some of the cameras. The processor is operable to generate a three dimensional vehicle representation. A display screen, viewable by a driver of the vehicle, is operable to display the generated images and the three dimensional vehicle representation as would be viewed from a virtual camera viewpoint exterior to and higher than the vehicle itself. A portion of the three dimensional vehicle representation is rendered as displayed to be at least partially transparent to enable viewing at the display screen of an object present exterior of the vehicle that would otherwise be partially hidden by non-transparent display of that portion of the three dimensional vehicle representation.

Abstract: A vision system for a vehicle includes a color camera that captures image data, which is processed using an in-line dithering algorithm. The in-line dithering algorithm determines most significant bits and least significant bits of first color data captured by a first photosensing element of a row or column, and the least significant bits of the first color data are added to second color data captured by a second photosensing element of the row or column to generate second adjusted color data. The in-line dithering algorithm determines most significant bits and least significant bits of the second color data, and the least significant bits of the second color data are added to third color data captured by a third photosensing element of the row or column to generate third adjusted color data.

Abstract: A vehicle vision system includes a plurality of cameras having respective fields of view exterior of the vehicle. A processor is operable to process image data captured by the cameras and to generate images of the environment surrounding the vehicle. The processor is operable to generate a three dimensional vehicle representation of the vehicle. A display screen is operable to display the generated images of the environment surrounding the vehicle and to display the generated vehicle representation of the equipped vehicle as would be viewed from a virtual camera viewpoint. At least one of (a) a degree of transparency of at least a portion of the displayed vehicle representation is adjustable by the system, (b) the vehicle representation comprises a vector model and (c) the vehicle representation comprises a shape, body type, body style and/or color corresponding to that of the actual equipped vehicle.

Abstract: A driver assistance system for a vehicle includes a plurality of sensors disposed at a vehicle and operable to detect objects at least one of ahead of the vehicle and sideward of the vehicle. The driver assistance system includes a data processor operable to process data captured by the sensors to determine the presence of objects ahead and/or sideward of the vehicle. Responsive to the data processing, the driver assistance system is operable to determine at least one of respective speeds of the determined objects and respective directions of travel of the determined objects. The driver assistance system is operable to determine respective influence values for the determined objects. Responsive to the respective determined speeds and/or directions of travel of the determined objects and responsive to the determined respective influence values, at least one path of travel for the vehicle is determined that limits conflict with the determined objects.

Abstract: A vision system for a vehicle includes a camera disposed at the vehicle and having a field of view exterior of the vehicle. The camera includes an RGB photosensor array having multiple rows of photosensing elements and multiple columns of photosensing elements. An in-line dithering algorithm is applied to individual lines of photosensing elements of the photosensor array in order to reduce at least one of color data transmission and color data processing. The in-line dithering algorithm includes at least one of an in-row dithering algorithm that is applied to individual rows of photosensing elements of the photosensor array and an in-column dithering algorithm that is applied to individual columns of photosensing elements of the photosensor array. The in-line dithering algorithm may be operable to determine most significant bits and least significant bits of color data of photosensing elements of the photosensor array.

Abstract: A lighting control system for a vehicle includes a controller configured to be disposed at a vehicle so as to connect with or communicate with at least one light of the vehicle. The controller, responsive to at least one input, adjusts a color of the at least one light of the vehicle and an intensity of the at least one light of the vehicle. The input may include one or more of (i) a driver attentiveness input and (ii) a driver age input, and optionally a time of day input, an ambient light input, a weather condition input, and/or a navigation input.

Abstract: A vision system of a vehicle includes a camera disposed at a vehicle and having a field of view exterior of the vehicle. The camera includes an imaging array having a plurality of photosensing elements arranged in a two dimensional array of rows and columns. The imaging array includes a plurality of sub-arrays comprising respective groupings of neighboring photosensing elements. An image processor is operable to perform a discrete cosine transformation of captured image data, and a Markov model compares at least one sub-array with a neighboring sub-array. The image processor is operable to adjust a classification of a sub-array responsive at least in part to the discrete cosine transformation and the Markov model.

Abstract: A multi-camera vision system of a vehicle includes at least four cameras disposed at a vehicle and having respective fields of view exterior of the vehicle. Each of the cameras is operable to capture image data representative of the respective field of view. Captured image data is compressed at the respective camera and the compressed image data is communicated to a control unit. The control unit includes an image processor operable to process image data. The image processor processes image data frame by frame using an indirect context model and without time wise dependency.

Abstract: A driver assist system for a vehicle includes a camera, a receiver and a control. The camera has a field of view exterior of the vehicle and is operable to capture image data. The receiver is operable to receive a wireless communication from a communication device disposed at another vehicle. The control includes a data processor that processes captured image data to detect objects. The wireless communication includes a car-to-car communication. The driver assist system, responsive at least in part to processing by the data processor of captured image data and to the wireless communication received by the receiver, determines a potential hazard existing in a forward path of travel of the equipped vehicle. The control, responsive at least in part to such determination, controls at least one vehicle function of the equipped vehicle to mitigate the potential hazard in the forward path of travel of the equipped 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 driver assist system for a vehicle includes an object detection sensor disposed at the vehicle and having an exterior field of view and a receiver operable to receive a wireless communication from a communication device remote from the vehicle. The wireless communication is associated with a driving condition of another vehicle and/or a road condition of interest to the driver of the vehicle. A control is operable to process data captured by the object detection sensor to detect an object exterior of the vehicle. The driver assist system is operable to adjust the data processing responsive at least in part to the received wireless communication. Responsive to the data processing, an alert is operable to alert the driver of the vehicle of a potential hazard and/or a system of the vehicle is operable to control a vehicle function to mitigate or avoid a potential hazard condition.

Abstract: A vision system for a vehicle includes a camera disposed at the vehicle and having a field of view exterior of the vehicle. The camera includes an RGB photosensor array having multiple rows of photosensing elements and multiple columns of photosensing elements. An in-line dithering algorithm is applied to individual lines of photosensing elements of the photosensor array in order to reduce at least one of color data transmission and color data processing. The in-line dithering algorithm includes at least one of an in-row dithering algorithm that is applied to individual rows of photosensing elements of the photosensor array and an in-column dithering algorithm that is applied to individual columns of photosensing elements of the photosensor array. The in-line dithering algorithm may be operable to determine most significant bits and least significant bits of color data of photosensing elements of the photosensor array.

Abstract: A vision system of a vehicle includes a camera disposed at a vehicle and having a field of view exterior of the vehicle. The camera includes an imaging array having a plurality of photosensing elements arranged in a two dimensional array of rows and columns. The imaging array includes a plurality of sub-arrays comprising respective groupings of neighboring photosensing elements. An image processor is operable to perform a discrete cosine transformation of captured image data, and a Markov model compares at least one sub-array with a neighboring sub-array. The image processor is operable to adjust a classification of a sub-array responsive at least in part to the discrete cosine transformation and the Markov model.

Abstract: A vehicle vision system includes a plurality of cameras disposed at a vehicle and having respective exterior fields of view and a display screen for displaying images derived from captured image data in a surround view format where captured image data is merged to provide a single composite display image from a virtual viewing position. A gesture sensing device is operable to sense a gesture made by the driver of the vehicle. A control provides a selected displayed image for viewing by the driver to assist the driver during a particular driving maneuver. The control is responsive to sensing by the gesture sensing device, whereby the driver can adjust the displayed image by at least one of (a) touch and (b) gesture to adjust at least one of (i) a virtual viewing location, (ii) a virtual viewing angle, (iii) a degree of zoom and (iv) a degree of panning.

Abstract: A vehicle vision system includes a plurality of cameras having respective fields of view exterior of the vehicle. A processor is operable to process image data captured by the cameras and to generate images of the environment surrounding the vehicle. The processor is operable to generate a three dimensional vehicle representation of the vehicle. A display screen is operable to display the generated images of the environment surrounding the vehicle and to display the generated vehicle representation of the equipped vehicle as would be viewed from a virtual camera viewpoint. At least one of (a) a degree of transparency of at least a portion of the displayed vehicle representation is adjustable by the system, (b) the vehicle representation comprises a vector model and (c) the vehicle representation comprises a shape, body type, body style and/or color corresponding to that of the actual equipped vehicle.

Abstract: A dynamic image stitching system for stitching images captured by multiple cameras of a vision system of a vehicle includes a first camera disposed at a vehicle and having a first field of view exterior the vehicle and a second camera disposed at the vehicle and having a second field of view exterior the vehicle. The first and second fields of view at least partially overlap. A processor is operable to process image data captured by the first and second cameras. The processor processes captured image data to determine characteristics of features or objects present in the overlapping region of the first and second fields of view. The processor is operable to adjust a stitching algorithm responsive to a determination of a difference between a characteristic of a feature as captured by the first camera and the characteristic of the feature as captured by the second camera.

Abstract: A vehicular vision system includes a camera disposed at a vehicle and having a field of view. The camera is operable to capture image data. The camera includes a pixelated array of photosensing elements. A lens array may be disposed at the pixelated array of photosensing elements. The lens array includes an array of lens elements for imaging light onto respective sub-arrays of photosensing elements of the pixelated array of photosensing elements. An image processor is operable to process captured image data and, responsive at least in part to image processing of captured image data, the vehicular vision system is operable to determine distance to an object present in the field of view of the camera.