Abstract:
Methods and systems for developing image processing in a vehicle are described. In an example, a system, a tool or method may be used to determine the effect of changing parameters for processing the image data from a vehicle camera without actually processing the image. The image may be processed after the parameters reach a threshold of minimum requirements. After the image is approved, the parameters may be stored and transmitted to a separate system to be integrated into head unit instructions of a vehicle or loaded into head unit memory in a vehicle. The vehicle may display a processed image in a vehicle display. Vehicle processing circuitry may develop image processing for a vehicle are described. In an example, the image processing that relates to preparing an image for display occurs in the head unit in the vehicle may be positioned away from the camera itself.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application claims the benefit of U.S. provisional application Ser. No. 62/364,630 filed Jul. 20, 2016, the disclosure of which is hereby incorporated in its entirety by reference herein. 
     
    
     TECHNICAL FIELD 
       [0002]    The present disclosure generally relates to image processing for vehicles and tools to develop image processing methods for motor vehicle applications. 
       BACKGROUND 
       [0003]    Cameras are used in vehicles to provide views of the surrounding environment to a driver. The camera can take an image and process the image and send the processed image to a display in the vehicle cabin for display. Setting the image for display in the vehicle can be computing intensive and take a significant period of time. 
       SUMMARY 
       [0004]    Methods and systems for developing image processing in a vehicle are described. In an example, a system, a tool or method may be used to determine the effect of changing parameters for processing the image data without actually processing the image. The image may be processed after the parameters reach a threshold of minimum requirements. After the image is approved, the parameters may be stored and transmitted to a separate system to be integrated into head unit instructions or loaded into head unit memory. 
         [0005]    Methods and systems for displaying a processed image in a vehicle are described. Methods and systems for developing image processing in a vehicle are described. In an example, the image processing that relates to preparing an image for display occurs in the head unit in the vehicle away from the camera itself. 
         [0006]    A vehicle image processing system is described. The vehicle image processing system may be part of a head unit for a vehicle, e.g., a passenger vehicle. The image processing system may include an image source to provide image data and an image processor to receive the image data and process the image data to output a display image according to processing parameters. The processing parameters may be generated by loading camera parameters, selection of output requirement parameters, selecting annotation settings, calculating a view of a raw image data, adjusting parameters, outputting adjusted view using adjusted parameters without recalculating the entire raw image, or combinations thereof. The processor may receive an indication that the image data passes image inspection. Thereafter, the image processor may set the processing parameters to output the display image for a specific vehicle to adjust for the camera type and operation and the output device in the vehicle. The system also includes a display to receive the display image and output the display image. 
         [0007]    In an example, the image processor processes the image data by repeating the process tasks, if the display image does not pass an inspection. The image processor may adjust one or more parameters and then output an adjusted view using adjusted parameters without recalculating the entire raw image. When the image data passes image inspection, the image processor sets the processing parameters to output the display image for a specific vehicle to adjust for the camera and output device. 
         [0008]    In an example, a head unit for a vehicle includes a memory to store the parameters for processing the image data when the processing passes inspection. 
         [0009]    In an example, the image processor processes the image data with parameters set without graphically processing a new output image from the raw image file. 
         [0010]    In an example, a global positioning system is used to determine a location of the vehicle and to set a location parameter based on the location of the vehicle. The image processor uses the location parameter to set processing to the raw image data or the previously processed image. The image processor can overlay the location parameters on the display data output at the vehicle display. The image processor can use the location data to change other processing parameters used to process the image. 
         [0011]    In an example, the image source is wide angle camera with a field of view greater than 130° and up to about 200°. The processing parameters are set to correct for at least some of distortion of the image data resulting from a wide-angle camera. 
         [0012]    In an example, the image processor is remote from the camera. 
         [0013]    Methods for processing images in a vehicle mounted imager are described. The method includes loading processing parameters to process an image from a vehicle camera, receiving a raw image file that was produced by a vehicle camera, processing the raw image file using the processing parameters to output a first output image, displaying the first output image, 
         [0014]    changing at least one of the parameter of the processing parameters, and outputting a reprocessed output image based on changed parameters without graphically reprocessing the raw image file. 
         [0015]    In an example, loading processing parameters includes loading a distortion strength parameter, a zoom level parameter, a vertical offset parameter, a horizontal offset parameter, and a tilt level parameter. 
         [0016]    In an example, changing at least one of the parameter of the processing parameters results a near real-time change in outputting a reprocessed output image. 
         [0017]    In an example, outputting a graphical user interface showing more than one of the processing parameters. 
         [0018]    In an example, outputting the graphical user interface includes a single screen interface to change most of the processing parameters and then output a sample image. 
         [0019]    In an example, outputting the graphical user interface includes outputting at least one of a perspective view 3D visualization diagram, overlay parameters, car parameters, and steering wheel angle parameter, and a combination thereof. 
         [0020]    In an example, outputting the graphical user interface includes receiving position data from a navigational positioning system, integrating the position data with the graphical user interface, and displaying the graphical user interface with camera produced video and the positional data from the navigational positioning system. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0021]      FIG. 1  illustrates a schematic view of a vehicle with an imaging system according to an embodiment of the present disclosure. 
           [0022]      FIG. 2  illustrates schematic view of a vehicle head unit according to an embodiment of the present disclosure. 
           [0023]      FIG. 3  illustrates a method for an imaging system according to an embodiment of the present disclosure. 
           [0024]      FIG. 4  illustrates a system for generating a vehicle image file according to an embodiment of the present disclosure. 
           [0025]      FIG. 5  illustrates a method for generating a vehicle image processing file according to an embodiment of the present disclosure. 
           [0026]      FIGS. 6A and 6B  illustrate a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0027]      FIGS. 7A and 7B  illustrate a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0028]      FIG. 8  illustrates a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0029]      FIG. 9  illustrates a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0030]      FIG. 10  illustrates a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0031]      FIG. 11  illustrates a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0032]      FIG. 12  illustrates a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0033]      FIG. 13  illustrates a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0034]      FIG. 14  illustrates a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0035]      FIGS. 15A and 15B  illustrate graphical user interfaces for a vehicle image generator according to an embodiment of the present disclosure. 
           [0036]      FIG. 16  illustrates a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0037]      FIG. 17  illustrates a graphical user interface for a vehicle image generator according to an embodiment of the present disclosure. 
           [0038]      FIG. 18  illustrates a schematic view of the camera and head unit generator according to an embodiment of the present disclosure. 
       
    
    
     DETAILED DESCRIPTION 
       [0039]    As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention. 
         [0040]      FIG. 1  is a schematic view of one example of a vehicle  100  with an imaging system  101 . The vehicle  100  includes different systems that interact to provide motive forces and provide a suitable environment for the user and passengers. Vehicle  100  can include an engine, transmission, and wheels. The engine can be an internal combustion engine, a hybrid engine, or an electric motivator. Vehicle  100  can further include cabin controls that can be used by the user to control the experience in the cabin and operate the vehicle. One such system is an imaging system that can produce views of the outside environment around the vehicle and reproduce them on one or more displays within the cabin. An example of an imaging system is a rear-view camera system, which can provide a rearward view from the vehicle (e.g., a scene behind the vehicle) and display the rear view to the driver. The imaging system may also provide video images of the environment to the side of the vehicle of in front of the vehicle. The images that are displayed in the vehicle must be processed from an imager, e.g., a camera sensor, to properly display and provide the desired appearance to the user with the vehicle cabin. 
         [0041]    Vehicle  100  can include a camera  101  that is mounted to the vehicle and looks outwardly of the vehicle. The camera  101  can be rear facing and, in an example, mounted in a bumper or other rear facing surface of the vehicle. The camera  101  being rear facing to permit the operator to view traffic conditions to rearward from left and right sides of the vehicle, as well as directly behind the vehicle. In an example, the camera is one of a plurality of cameras, which can be rear facing with a left video camera and a right video cameras mounted on the left and right sides of the motor vehicle forwardly of the driver&#39;s position. Camera  101  can be a small CMOS imager. Other imagers may be used. Camera  101  can be housed in a canister of about one centimeter to about three centimeters in diameter by about three centimeters in length. The camera  101  may include a small fixed-focus or variable-focus lens that focus light on the solid-state imaging chip. The camera lens can be normal or wide angle or can be a zoom arrangement which is movable between normal and wide positions. A wide-angle lens can provide a video image with a field of view in a range of about 130° to 200°, +/−5°, or +/−10° or 15°. Such a wide-angle lens in the camera  100  presents a significantly distorted image and presents technical challenges to displaying the video image. It is desirable to correct for some of the distorted, e.g., fish eye, effects of these types of wide-angle cameras. Image processing can be used to adjust a raw camera produced image for display in a vehicle. 
         [0042]    The camera  101  outputs video image data  103 . Image processing can be performed at the camera  101  to format the video image for display in the vehicle. The image is focused using a lens on the imager. An image signal processor produces an image suitable for display. The video data processed by the image signal processor is serialized and sent to a de-serializer and displayed on a screen. Conventionally, this serialized signal is not raw image data. In examples of the present disclosure, the image signal includes a raw image data. In an example, the image data is a raw image  103  that is sent to the vehicle&#39;s head unit  105 . The head unit  105  is positioned remotely from the camera. The head unit  105  can be mounted in the vehicle cabin, e.g., under the dashboard, in the center of the dashboard, in a center console, beneath a seat or combinations thereof. The head unit  105  includes an image signal processor  111  that uses processing parameters  113  to process the raw image(s) (e.g., a video)  103  into a form suitable for transmitting to the display  107 . The image signal processor  111  can insert overlays onto the image output to the display  107  and can compute the location of objects in the video image. The image signal processor  111  can also correct for the distortion effects produced by using a wide-angle lens in the imager  101 . The image signal processor  111  can also receive navigational positioning information, e.g., from a global positioning system (GPS), and integrate the navigational positioning information into the video for output on the display  107 . The display  107  can be a liquid crystal display in communication with circuitry in the head unit  105 . 
         [0043]    The head unit  105  can operate to process a plurality of functions in a vehicle in addition to image signal processing for display. The head unit can provide infotainment to the vehicle occupants, e.g., play music, provide navigation instructions, perform voice recognition, mobile communications, store the owner&#39;s manual and the like. These functions can be performed in parallel with the image processing. In an example, a same digital signal processor in the head unit  105  can be used for processing the raw image into an image suitable for display. 
         [0044]      FIG. 2  illustrates a head unit  105  installed in a vehicle  100 . The head unit  105  can include various modules that operate to provide various functions, which may be different than those described herein. A processor  201  is provided to execute instructions on data stored in the head unit or from sensors in the vehicle. An image processor  203  may be provided to work in parallel with the processor  201 , in some examples. In other examples, the processor  201  processes the raw image data into a form for display. A memory  205  is proved to store data needed by the head unit  105 . The memory  205  can store data relating to any function of the head unit and instructions for execution be at least one of the processor  201  or the image processor  203 . The memory  205  can store image data and instructions for processing the image data into a form for presentation on the display  107 . The image processing data in the memory can include a look-up-table that has parameters to process the raw video image. The look-up-table (LUT) can be particular to a specific vehicle type and a specific model, and possibly a specific trim package. The LUT can be downloaded and is specific to the specific configuration of the vehicle. A wireless module  207  allows the head unit to communicate via short range wireless, e.g., Bluetooth, or long range wireless, e.g., cellular or Wi-Fi. A USB interface  209  is provided to allows data upload or download. The audio out  211  can output audio data, e.g., to speaker  219 . A navigation module  213  can provide navigation instructions, maps, and location information. An audio processor  215  can process audio signals, e.g., satellite radio, radio, digital files, and the like. An input/output module  217  allows input and output signals to be sent to the head unit  105 . The display  107  is connected to the head unit  105  and can provide visual indicators for any of the functions of the head unit. A satellite positioning module  221 , e.g., a global positioning system device, is in communication with the head unit  105 . A human-machine-interface module  225  is provided in the vehicle to allow a person to interact with the head unit. The head unit  105  can also operate to process the raw camera image into a form for display at the display  107 . 
         [0045]      FIG. 3  illustrates a method  300  for displaying an image in a vehicle. At  301 , an image of the external environment is captured using an image (e.g., a CMOS chip or a CCD chip in the camera) that is pointed outwardly from the vehicle. The image can be a raw image that is not processed at the imager or is minimally processed to a form for electrical communication to the head unit. At  303 , the raw image data is transmitted to the head unit. In an example, the video data is serialized to transmit the data over an electrical line to the head unit, which can de-serialize the video data. The imager can also packetize the video data to send to the head unit. At  305 , the raw image data is processed by the head unit, e.g., for display on a display in the vehicle. At  307 , the processed image is displayed. 
         [0046]    The head unit  105  can operate on instructions loaded into a processor to out a video image from a camera on a display that has various features relative to the raw or source image data. The viewing image that is output to the display may be a rear view that capture a first minimum height at the lowest portion of a vertical band on target F and target G and a second minimum height above the highest portion of the horizontal band on targets A, B &amp; C, with reference to the raw image shown in  FIG. 12 . The target image can also be used to set skew, rotation and other processing parameters for producing an output image for display. The viewing image output by the head unit may default to a rear view if vehicle movement state is invalid or unavailable. The head unit may down sample the image or show fewer frames per second in low light conditions to enhance image quality. The head unit will have the ability to detect an incorrect/stuck or frozen image. The head unit may allow a user to enable/disable backup overlay guidelines using customization menu or inputs, e.g., from steering wheel controls or touch screen controls. The head unit can overlay steering guidelines on the output image that represent the width of the rear end of the vehicle. The steering guidelines depend on steering wheel or tire position(s), which are input into the image processor. The head unit can dynamically adjust the steering guidelines to show the projected path of the vehicle based upon the steering angle, vehicle dimensions and vehicle velocity. The head unit may further reduce the steering overlay to not block the obstacles in the image. The head unit may also detect obstacles and unavailable features and send a warning to a driver regarding obstacles or unavailable features. The head unit may only use steering overlays if they do not block obstacles in the image. 
         [0047]      FIG. 4  illustrates a schematic view of a graphical user interface  400  for generating a file or parameters to control displaying a video image. The interface  400  organizes the image that is being evaluated with the various inputs that are applied to the image to determine the parameters to process a raw image to produce a display of a processed video image. The graphical user interface  400  is shown on a display in communication with a processor that is dedicated to execute instructions to determine parameters for processing a raw video image, e.g., from a camera mounted in a vehicle, for display on a display in the vehicle. The cameras in vehicles are typically wide angle imagers, e.g., in a field of view greater than 130° and up to about 200°. This wide-angle imaging creates distortions in the image that should be corrected before showing the video image to a vehicle operator. The present graphical user interface  400  provides a single screen to change most of the image processing parameters and then output a sample image. If the sample image is sufficient, the parameters are saved and output to use in programming the image processing algorithm or module in the head unit. The processing parameters can be output in a look up table or other data record that is dedicated to the type of vehicle and the type of camera. The interface  400  includes a camera parameters input  403  to allow the input of various camera settings that are particular to the type of camera. The interface  400  includes a view settings control  405  that allows a user to change view settings to allow the settings to be changed in real-time and the effect of the changes can be calculated on the raw image and output for viewing and approval by the image processor. The interface  400  includes an annotation settings field  407  that allow the user to select which annotations will be included in the output image. Having annotations shown on the output image for review, allows a user to visually identify certain characteristics in the output image easily and to identify changes. The interface  400  includes a view output requirements field  409 , which are requirements by the vehicle manufacturer. These are requirements for the output image. Output controls  411  allow a user to select the type of output from the present algorithm. 
         [0048]      FIG. 5  illustrates a method  500  for generating an output image for display in a vehicle. At  501 , camera parameters are loaded into the algorithm or image processing parameter module. The camera parameters can include certain characteristics that are performance characteristics of the camera. At  503 , the output requirements are set. The output requirements are the requirements by the manufacturer relating to the image that will be output by the head unit to a vehicle operator. Some of the output requirements may be set by governmental entities or standards bodies. At  505 , the annotations settings are set. The annotation settings indicate what information, e.g., overlays and positional information, are shown on the resulting image that is processed according to the present method  500 . At  507 , the view settings are selected. The view settings may set other control settings for processing the raw image into an output image. Examples of view settings include, but are not limited to, distortion strength, zoom level, vertical offset, horizontal offset, and tilt level. With these settings and output requirements being set, a raw image is input at  509 . At  511 , the review view is calculated using the raw image and the parameter settings and requirements. At  513 , the review image is displayed and inspected. If the review image is approved for production, then the image processing parameters that created the review image are generated and saved (step  523 ). These image processing parameters can be encrypted to prevent alteration. The image processing parameters can be used to produce an algorithm, head unit parameters or a look up table of parameters that can be used to process a video image in a head unit to output the video image on a vehicle display. 
         [0049]    In operation, the changing of the settings or parameters, e.g., in step  515 , which may result a near real-time change in the results. At  517 , the view is re-calculated. Re-calculating may include providing information about compliance with view requirements without graphically processing a new output image from the raw image file. By showing the view requirements when parameters or settings are changed, the designer user can see compliance of the potential output image without graphically reprocessing the raw image to the output image. In an example, a change in the settings or parameters does not go back to the raw camera image file or to the image file received from the camera. The current image can be modified by the changes in real time with the image as previously processed. 
         [0050]    At  519 , the new image is show to see if the requirements are now passed. At  521 , a determination of whether the display image has passed. If the newly shown display image does not pass, then the process returns to step  515  to further adjust at least one of the settings and parameters. If the display image passes, then at  523  the image processing parameters are set. These image processing parameters can be encrypted to prevent alteration. The image processing parameters can be used to produce an algorithm, head unit parameters or a look up table of parameters that can be used to process a video image in a head unit to output the video image on a vehicle display. 
         [0051]      FIGS. 6A and 6B  illustrate a view of a graphical user interface  600  for three use cases, parabolic view, perspective view and overlay. The parabolic view tab is used for steps in generating a file or parameters for displaying video images from the exterior facing rear camera in a vehicle. The views from the imagers or cameras are parabolic due to the wide-angle lenses on the imagers or cameras. The perspective view tab is used to display the real camera position and allow adjustment of the virtual camera position for the desired perspective view transformation. The real camera position is set by the “Translation” and “Rotation” parameters in the camera parameters section  603  of the graphical user interface  600 . The overlays tab is to be used for checking overlay guide lines against geometry of the car. The overlay guide lines can show the predicted travel direction of the vehicle. 
         [0052]    The interface  600  includes various inputs that allow a user to change parameters for processing the raw image. A raw image window  601  provides a space to show the raw image that is being processed using settings and parameters that can be set or changed in the interface  600 . The parameters on the interface include common parameters, which are shared across all three tabs i.e., the parabolic view tab, the perspective tab and the overlay tab) and the parameters specific for a given tab. A tab is a selected region in the graphical user interface that allows the user to select a different portion of the graphical user interface  600  and different functionality for the interface  600 . The common parameters on the interface are camera parameters  603  and annotation settings  625 , as well as various output control buttons  630  are provided to allow the user to select the output from the video image processing methods and systems described herein. Drop down menus such as File, View, Tools and Help may also be provided. The View and Tools drop down menus allow access to some of the input features shown on interface  600 . The parabolic view tab&#39;s specific parameters are view validation parameters  605 , view settings  615 . The perspective view&#39;s tab&#39;s specific parameters are Perspective View Visualization  602  and Virtual Camera Position  616 . The overlay tab&#39;s specific parameters are Car Parameters  621 , Overlay Parameters  627  and Steering Angle  634 . 
         [0053]    Common camera parameter  603 , which can be shown as input fields in the interface, are shown. The camera parameters define features of the camera that is being used in the vehicle. The camera parameters can be provided by the camera manufacturer. The camera parameters  603  may include the focal length (e.g., in mm), which defines the focal length of the lens in the camera that is to be used in the vehicle. The camera parameters  603  may include the principal point input, which allows the input of the center pixel location of the camera as a coordinate. The camera parameters  603  may include the pixel size, e.g., in μm. The camera parameters  603  may include the lens distortion coefficient, which may include a value representing a divergence from rectilinear projection caused by a change in magnification with increasing distance from the optical axis of an optical system. The camera parameters  603  may include the translation value, which may be a mounting location, e.g., coordinates. The camera parameters  603  may include the rotation value, which can be the pitch of the mounting position of the camera (e.g., degrees rotated). These parameters can be used as processing parameters to produce an image to show on a display. 
         [0054]    Additional common parameters are Annotation Settings, which allow a user to select the annotations on the processed image. Examples of annotations include, but are not limited to, auto-calculate, which when selected causes the system to automatically calculate a new image result for review when the sliders in the view settings are released. The field of view boundary, when selected, overlays an indicator on the resulting processed image that shows the field of view that will be output to a vehicle display. In  FIG. 12  described below, this indicator is shown as a green ellipse but with defined corners. The image within the indictor will be shown as the output image. The E and D angles setting enable/disables the annotation of target E and D on the output image. These angles are the angle from true vertical of the targets D and E. The horizontal distance setting enables and disables horizontal distance annotations in the output image. The field of view (FOV) setting enables and disables the field of view annotations in the output image. 
         [0055]    The graphical user common interface  600  further provides Output Control Buttons  630  that allow a user to produce an output using the settings and parameters. The output controls buttons  630 , when selected can calculate a new output image, generate the look up table, perform error correction in the look up table (e.g., checksum), show the output image and show the raw image. 
         [0056]    The interface  600  for the Parabolic View tab includes view validation parameters  605 , which can be shown as input fields in the interface. The validation parameters  605  can be manufacturer requirements for the final image to be displayed by the head unit. The validation parameter fields can include the names of the parameters, a computed value  607  (which is blank in GUI  600  as an image has not been selected for processing), a minimum value in column  609 , a maximum value in column  611  and an indicator of pass or fail on column  613 . The validation parameters may include, but are not limited to the following: the left top corner position, the right top corner position, the left bottom corner position, and the right bottom corner position. The corner positions can all be defined as a percentage of the height of the raw image. The validation parameters may also include a target D angle and a target E angle, which are the angles from vertical for the targets D and E, respectively. The target labels are shown in subsequent views. The validation parameters may also include a horizontal distance distortion, e.g., at the center and at the bottom. These can be expressed as percentages and measured as the amount of curvature in a line that would be horizontal in the real world before the distortion effects of the wide-angle camera lens. The validation parameters may also include a reference point, which may be the number of pixels from bottom to a manually selected reference point divided by total image height. This can be used to define the percentage or part of the image that includes part of the vehicle, e.g., the bumper. The validation parameters may also include image field of view parameters, e.g., horizontal, vertical and diagonal field of views, which can be expressed as degrees or percentages. 
         [0057]    The interface  600  includes view settings  615 , which can be shown as control input fields in the interface. The control input fields can be filed in which a value can be typed in and/or can include slider bars to select the value, which can then be shown in the input field. These view settings are used to process a raw video image and produce an image to be evaluated for producing an image to display from the head unit or to a vehicle operator. The view setting  615  may include a distortion strength parameter  617 , a zoom level  618 , a vertical offset  619 , a horizontal offset  620 , and a tilt level parameter  621 . Each of these may be adjusted by moving the slider or by typing a new value into the adjacent input box. The distortion strength parameter  617  may be the percent of distortion correction applied from 0% (no correction) to 100% (full linear correction) to the raw image. The zoom level  618  is the amount of zoom as a percent of the original image. The vertical offset  619  is the vertical offset from the center of the original raw image. The horizontal offset  620  is the horizontal offset from the center of the original raw image. The tilt level parameter  621  corresponds to a virtual camera position when doing a perspective shift on the original image. The user can adjust these parameters and produce new images efficiently to see the changes caused by parameter changes. 
         [0058]    In operation, the changing of any of the view settings  615  results a near real-time change in the results at the view validation parameters  605 . The new output image need not be graphically processed and shown as a graphic view for the changed view settings to change the results in the view validation parameters  605 . By showing the view requirements when parameters or settings are changed, the designer user can see compliance of the potential output image without graphically processing the output image. The value for each of the view validation parameters in column  607  is compared to the minimum and maximum thresholds in columns  609  and  611 . When the value is within the range, or equal to the range boundaries, then the view validation parameter (column  607 ), then the validation parameter is indicated as pass or valid in column  613 . 
         [0059]      FIG. 7A  shows the interface  600  for perspective view tab includes perspective view 3D visualization diagram  602 , which shows 3D relative position between real and virtual camera. It also includes sliders and input fields for virtual camera position/orientation  615 . The control input fields can be filed in which a value can be typed in and/or can be modified by moving slider bars to select the value, which will then be represented in the input field. X parameter  604  is virtual camera position from the origin in the X direction as defined in the perspective view window, measured in millimeters. Y parameter  606  is virtual camera position from the origin in the Y direction as defined in the perspective view window. Measured in millimeters. Z parameter  608  is virtual camera position from the origin in the Z direction as defined in the perspective view window, measured in millimeters. Changing this value accomplishes a zoom in or out. Yaw parameter  610  is rotation around the Z-axis in degrees. Pitch parameter  612  is rotation around the Y-axis in degrees (correct to roll). Roll parameter  614  is rotation around the X-axis in degrees (correct to pitch). When, these parameters are changed after the raw image is processed, the image processor does not start processing at the raw image. Instead the image processor, which receives its input from the graphical user interface only changes the display image to a new display image. 
         [0060]      FIG. 7B  shows the interface  600  with the overlays tab selected, which replaces the 3D perspective representation or the view validation section with a car parameters interface  621  and overlay parameters interface  628 . The interface  600  for overlays tab includes car parameters  621 , overlay parameters  627  and steering wheel angle parameter  634 . 
         [0061]    Car parameters  621  consists of list of control input fields where value can be input into the graphical user interface. It may include following parameters. A wheelbase parameter  622  is distance between the centers of the front and rear wheels, e.g., in mm. An origin to rear axle distance parameter  623  is distance from rear axle to back edge of rear bumper, e.g., in mm. A steering wheel to front wheel ratio parameter  624  is an inverse steering ratio for front wheel, which can include a conversion from degrees to radians. A steering wheel to rear wheel ratio parameter  625  is an inverse steering ratio for the rear wheel, which can include conversion from degrees to radians. A maximum steering wheel angle parameter  626  is the hand wheel angle where steering ratio becomes invalid (relation between steering wheel and front wheel becomes nonlinear). A hitchball to ground plane distance parameter  627  is a distance between the center of the hitchball and ground plane, e.g., in mm. These parameters may depend on the specific type of vehicle that the image processor is producing an image. 
         [0062]    Overlay parameters interface  628  is composed of radio buttons  629  and control input fields where value can be input  631 - 635 . Radio buttons  629  enables the user to choose one of the three possible options: standard view which is parabolic view with standard overlay parking guidelines; perspective view perspective—being view with trailer overlay guidelines; standard View+Trailer which includes guidelines in parabolic view with trailer overlay guidelines. A track width field  631  is lateral distance between guidelines, e.g., in mm. A distance marker delta field  632  is longitudinal distance between distance marks. A distance marker number field  633  is number of markers to show. A longitudinal offset field  634  is distance from back edge of rear bumper to center of hitchball. This field  634  may be available only in Perspective View or Standard View+Trailer Guidelines modes. A distance marker length field  635  is length of distance marker line. This field may only be available only in Perspective View or Standard View+Trailer Guidelines modes. Thus, some of these fields are not available in all views on the interface. When a field is not available, then it will not accept input from a user. The fields each represent a single processing parameter for the image processor to use to output an image file for a display. 
         [0063]      FIG. 8  illustrates a view of a graphical user interface  700  for a step in generating a file or parameters for displaying video images from the exterior facing camera in a vehicle. The graphical user interface  700  is similar to the graphical user interface  600  but shows a further processing step with the raw image loaded into the image field  601 . The raw image can be a model image that is used to calibrate the parameters in the look up table for use in a vehicle. The targets A-G are shown in this image. The camera parameters  603  are input. All of the annotation settings  625  are selected. The distortion strength parameter  617  and a zoom level  618  are changed relative to the GUI  600 . The values in the output image are calculated and shown in value column  607  for each validation parameter  605 . An indicator of whether the value for the validation parameter meets the parameter limitation is shown in column  613 . The user need not process a full image to determine if the current settings and parameters meet the requirements in validation settings  605 . If the resulting output image is calculations are acceptable to the user, then the user can select the show output image button  705  to have the system and method produce an output image from the raw image. Processing images takes significant time relative to the calculations done to determine if the settings and parameters pass or fail the validation parameters  605 . Thus, the present interface  600 ,  700  allows a user to quickly change parameters and settings to produce an output image that is likely to be acceptable. 
         [0064]    As shown in the graphical user interface  700  some parameters of the resulting image as shown in section  701 , which can be a raw image or a processed image, do not pass the required values. For example, the left-top corner, the right-top corner and the horizontal distance (center) and the horizontal distance (lower round) are not within an acceptable range. The processing parameters must be changed to bring the image into compliance with the vehicle specifications. 
         [0065]      FIG. 9  illustrates a graphical user interface  800  for a step in generating a file or parameters for displaying video images from the exterior facing camera in a vehicle. The graphical user interface  800  is similar to the interfaces  600 ,  700  and shows the raw image loaded into the image field  601 . Additional validation parameters are shown in  605 , along with their values and whether they pass or fail the parameter limits. Interface  800  further shows additional changes to the distortion strength  617  and the zoom level relative to interfaces  600 ,  700 . These changes will change the calculated values for validation parameters  605  as shown in column  607   
         [0066]      FIG. 10  illustrates an output image  900  from the graphical user interface  800 . This output image  900  is processed according to the parameters and settings in interface  800  and represents and processed image in the output image window, which can be part of any of the interfaces described herein. The output image  900  can be displayed on any display connected to the image processor and need not be the same display as that used in the vehicle. The parameters and values in the interfaces  600 ,  700  include the specifications for the actual display for the vehicle. The annotations  908 - 913  are shown and illustrate the field of view annotations  908 , the horizontal distance annotation  913 ,  914  (as percentages, e.g., 0.96% and 11.98%) and the angles of targets E and D  911 ,  912  relative to vertical (13.69 degrees and 14.44 degrees, repsectively). The values annotated in the interface  900  are the actual computed values in the image. 
         [0067]      FIG. 11  illustrates a graphical user interface  1000  of an output image for display in a vehicle or to determine parameters to for processing video data to generate a display. This output image in  FIG. 11  is the same as image  900  without the annotations. The annotation settings  625  are all deselected to produce the output image  1000 . 
         [0068]      FIG. 12  illustrates a view of a graphical user interface  1100  of an output image for display in a vehicle or to determine parameters to for processing video data to generate a display. In view  1100 , the test image is shown with various annotations overlaid on the test image. The annotations can be selected at the graphical user interface  600  in the settings  625 . An image frame  1101  is overlaid on the test image. This can be selected by selecting the FOV boundary on the settings  625 . The image frame  1101  indicates the portion of the raw image, here, a test image, that will be the processed image to be shown on display when the head unit outputs the image. The corners  1105 ,  1106 ,  1107 , and  1108  can be set by selecting the corner and moving the indicator (here, a red cross) to change the position of the corner. The top left corner  1105  is positioned at 84.10%. The top right corner  1106  is positioned at 84.05%. The bottom right corner  1107  is positioned at 14.49%. The bottom left corner  1108  is positioned at 14.44%. The new positions of the corners are fed back into the algorithm for determining the parameters for processing a video feed. The field of view boundary sets the area of the image that will be shown a display in the vehicle. This area is of principle review for compliance with output image requirements. 
         [0069]    The field of view data relating to the portion of the raw image in the image frame  1101  are shown at  1115 . This can be selected by selecting the FOV setting on the settings  625 . Examples of the field of view data include, but are not limited to, field of view horizontal, field of view vertical, and field of view diagonal. These variables can be shown as angles, here, 152.04 degrees, 119.45 degrees and 159.40 degrees. 
         [0070]    A frame  1110  is overlaid on the image and shows the end display resolution. This allows the intermediate output from the parameter developing method to visualize the distortion correction, e.g., as a percent distortion correction. 
         [0071]    The image  1100  further shows various obstacles that are referred to in the present disclosure, these obstacles represent targets A, B, C, D, E, F, and G that are used in the image processing. Fewer or more targets may be used in a test image. 
         [0072]      FIG. 13  illustrates a perspective view visualization of the graphical user interface produced by the image processor. The selection area  1300  represents total pixels area from original raw image that will be taken to perspective view transformation. The resulting output image  1400  is shown on  FIG. 14 . 
         [0073]      FIGS. 15A and 15B  illustrate an overlays visualization for the graphical user interface. The view of  FIG. 15A  shows the graphical user interface for inputting processing parameters. The overlay preview  1500  in  FIG. 15B  shows the selected view from  FIG. 15A . The overlay preview  1500  will allow user to check the layout of overlay guide lines against test points/lines in raw images or previously processed images. 
         [0074]      FIG. 16  and  FIG. 17  shows overlay testing points/lines on the output image from the image processor and on the raw, input image, respectively. 
         [0075]      FIG. 18  shows a more detailed view of a system  1200  with a camera  101  for a vehicle that produces video image data and sends it to a head unit  105  for processing to be displayed in the vehicle. The camera  1201  includes an image sensing core  1201  that receives light through a lens  1202 . The lens  1202  may be a wide angle lens or other lens that produces distortion that must be corrected before display at the vehicle display  107 . An input/output module  1203  receives the image data and prepares it for transmission over the busses  1204  or  1026  to the head unit  105 . The head unit  105  includes an automatic control module  1207 , which can produce gain control for processing the image data. The head unit  105  includes the image processor  1210 , which can use the parameters or look up table described herein to process the video image data and output a processed image to the display  107 . 
         [0076]    The described methods and systems allow an engineer or designer to change and select parameters and settings for generation of an output image. Individual parameters and settings can be changed and its effect on the resulting output image can be calculated and displayed in a graphical user interface without processing the entire image and inspecting the image. The output image can be produced to inspect the image and validate the computed result. 
         [0077]    The embodiments of the present disclosure generally provide for a plurality of circuits or other electrical devices to perform the methods and build some of the operational portions of the structures and systems. All references to the circuits and other electrical devices and the functionality provided by each, are not intended to be limited to encompassing only what is illustrated and described herein. While particular labels may be assigned to the various circuits or other electrical devices disclosed, such labels are not intended to limit the scope of operation for the circuits and the other electrical devices. Such circuits and other electrical devices may be combined with each other and/or separated in any manner based on the particular type of electrical implementation that is desired. It is recognized that any circuit or other electrical device disclosed herein may include any number of microprocessors, integrated circuits, memory devices (e.g., FLASH, random access memory (RAM), read only memory (ROM), electrically programmable read only memory (EPROM), electrically erasable programmable read only memory (EEPROM), or other suitable variants thereof) and software which co-act with one another to perform operation(s) disclosed herein. In addition, any one or more of the electric devices may be configured to execute a computer-program that is embodied in a non-transitory computer readable medium that is programmed to perform any number of the functions as disclosed. 
         [0078]    A vehicle may have a user interface system that may communicate with one or more nomadic devices. The user interface system may include, but is not limited to, a vehicle computing system, a display, and at least one connection apparatus to communicate with one or more nomadic devices. A user may interface with the one or more nomadic devices using the vehicle interface system. The one or more nomadic devices may contain several applications that may be compatible with the interface system for operation of a feature and/or function. The applications may be executed on the nomadic device, system, and/or a combination of both; and the output data may be presented to a user at the interface system. 
         [0079]    The one or more nomadic devices communicating with the interface system may experience different management, output, and/or display of content based on the connected nomadic device operating host (e.g., Android, Windows, iOS, etc.). A user of the system may want a user interface paradigm that offers no discernible difference to the user between nomadic devices that are communicating to the system using different operating hosts. The nomadic device may download the parameters or look up table to the head unit. 
         [0080]    The image processor as described herein is used with a head unit of a vehicle. The image processor may also be part of a design system that is outside of a vehicle and used to determine the processing parameters for a specific vehicle type, a specific imager, a specific display, or combinations thereof. Thus, the processing parameters in the image processor may be used outside the vehicle to determine the acceptable processing parameters that are to be used with any specific vehicle set up. 
         [0081]    The present systems and methods provide an efficient means for determining the parameters for processing image data for display in a vehicle. The parameters are dependent on the type of lens, type of camera, position of camera on the vehicle, type of vehicle, trim of vehicle, type of display, manufacturer requirements, etc. There is a need, as discovered by the present inventors, for systems and methods to address the all of these variables while reducing processing time. Processing new images each time a variable of parameter requirement changes is time consuming. Examples of the present systems and methods load the image requirements into a module along with the camera properties. Certain controllable parameters are provided at a graphical user interface and the result of changing these parameters is shown graphically without processing the image as a whole. When it is determined that the parameters meet enough of the display requirements, then the graphical user interface can instruct the system to process the image to produce an example of the output image. The output image may include various data points and annotations to assist in its review. When it is determined that the output image is acceptable, then the system or method, stores the parameters. The stored parameters are then converted into a form that can be used for that specific vehicle type and loaded into a vehicle head unit, which may process the image data from the camera to output video images on a vehicle display. 
         [0082]    The images sensed by a camera mounted in a vehicle are displayed in the vehicle. The cameras used in vehicles have a wide-angle lens, which distorts the image that is sensed by the image sensor. This distorted image data is sent to the vehicle head unit for processing into a form suitable for display on a display, e.g., a flat panel display. The processing relies on parameters that are dependent on the type of lens, type of camera, position of camera on the vehicle, type of vehicle, trim of vehicle, type of display, etc. These parameters are stored in the head unit memory and used by processors in the head unit to correct the image data for display. 
         [0083]    The vehicle  100  can include an on-board GPS-based navigation system to sense the position if the vehicle using signals from satellites. The navigation system can include processor, memory, GPS receiver, and communication unit  28 . The position data can be used to provide navigation information on a map on the vehicle. The position of the vehicle as determined by the navigation system can be used to further refine the image from the cameras shown in the vehicle. The memory can be used to store software and data for processor to carry out various operations of navigation system. The stored software may include a navigator web browser for browsing information provided, e.g., by servers connected to the Internet. In particular, the navigator browser works compatibly with the standard hypertext transfer protocol (HTTP), hypertext markup language (HTML), virtual reality markup language (VRML), graphics interchange format (GIF), JAVA applets, etc. 
         [0084]    The vehicle may include a display, e.g., a liquid crystal display (LCD). Through a display driver, the processor controls the display of text, graphics and camera generated image on the display as processed according to the parameters as described herein. A user interface may comprise conventional audio circuitry including a microphone and speaker for the user to communicate with navigation system via audio media. The user interface may also comprise an indicator device, e.g., a mouse, touchpad, roller ball, or a combination thereof, which may enable a user to move a cursor on display and to point and click at a displayed option or an icon to select same. In addition, the user interface may incorporate well-known touch-screen circuitry (not shown). With this circuitry, the user can interact with the processor by using a finger or a stylus to touch the surface of display, which is tactile-sensitive. The processor receives from the touch screen circuitry a signal identifying the location on the display where it has been touched. If such a location matches the predetermined location of one of displayed options or icons, the processor determines that the option or icon has been selected. Otherwise, a cursor is placed at the touched location on display, prompting for an input from the user. 
         [0085]    The present disclosure uses the term “tabs” to describe a selectable icon component in a graphical user interface that provides a man-to-machine interface. A tab can be selected using an input device, e.g., a keyboard, a mouse, a touch screen, a joy stick, a pointing device or the like. The tab being selected will cause the system to provide additional selectable icons or input boxes or regions or the like. 
         [0086]    While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.