Abstract: Systems (490), methods (340), and machine-readable and executable instructions (428) are provided for depth mask assisted video stabilization. Depth mask assisted video stabilization can include creating a first depth mask from a first frame (101, 201) and a second depth mask from a second frame (102, 202) to obtain depth information (342) and defining a first list of feature points (111-1a, 111-2a, 111-3a, 111-4a, 113-1a, 113-2a, 113-3a, 113-4a, 113-5a) from the first frame (101, 201) and a second list of feature points (111-1b, 111-2b, 111-3b, 111-4b, 113-1b, 113-2b, 113-3b, 113-4b, 113-5b) from the second frame (102, 202) (344).

Abstract: Systems, methods, and other embodiments associated with producing spatially varying spectral response calibration data are described. One example method includes controlling a digital camera to capture characteristic data arrays from light sensors in the digital camera in response to the digital camera being exposed to light stimuli from a multi-spectral reference display. The data arrays will be acquired multiple times at multiple locations in multiple stimuli provided from the multi-spectral reference display. The method also includes controlling a calibration logic to manipulate characteristic data arrays to produce spatially varying spectral response calibration data as a function of using characteristic data arrays and known wavelengths of the light in light stimuli. The method may also include providing the spatially varying spectral response calibration data to a downstream consumer (e.g., correction process, quality control process), displaying the data, or storing the data.

Abstract: Systems (490), methods (340), and machine-readable and executable instructions (428) are provided for depth mask assisted video stabilization. Depth mask assisted video stabilization can include creating a first depth mask from a first frame (101, 201) and a second depth mask from a second frame (102, 202) to obtain depth information (342) and defining a first list of feature points (111-1a, 111-2a, 111-3a, 111-4a, 113-1a, 113-2a, 113-3a, 113-4a, 113-5a) from the first frame (101, 201) and a second list of feature points (111-1b, 111-2b, 111-3b, 111-4b, 113-1b, 113-2b, 113-3b, 113-4b, 113-5b) from the second frame (102, 202) (344).

Abstract: Systems, methods, and machine-readable and executable instructions are provided for filtering image data. Filtering image data can include determining a desired depth of field of an image, determining a distance between a pixel of the image and the desired depth of field. Filtering image data can also include adjusting a contrast of the pixel in proportion to a magnitude of a weight of the pixel, wherein the weight is based on the distance.

Abstract: Systems, methods, and other embodiments associated with producing spatially varying spectral response calibration data are described. One example method includes controlling a digital camera to capture characteristic data arrays from light sensors in the digital camera in response to the digital camera being exposed to light stimuli from a multi-spectral reference display. The data arrays will be acquired multiple times at multiple locations in multiple stimuli provided from the multi-spectral reference display. The method also includes controlling a calibration logic to manipulate characteristic data arrays to produce spatially varying spectral response calibration data as a function of using characteristic data arrays and known wavelengths of the light in light stimuli. The method may also include providing the spatially varying spectral response calibration data to a downstream consumer (e.g., correction process, quality control process), displaying the data, or storing the data.

Abstract: Systems and methods for camera sensor correction are disclosed. In an exemplary embodiment, a method may include sampling a spectral response for a plurality of color channels at different spatial locations on a sensor. The method may also include applying a 4×4 color correction matrix at the different spatial locations in an image captured by the sensor. The method may also include converting the spectral response at each spatial location to match the spectral response of the sensor at any one location on the image.

Abstract: A method is provided for correcting a captured image. The method comprises determining an illuminant for the captured image. When the determined illuminant matches a reference illuminant the image is corrected with a reference inversion mask. When the determined illuminant matches a first extreme illuminant, the reference inversion mask is modified using a first set of reference point ratios that corresponds to the first extreme illuminant and the image is corrected with the modified inversion mask. When the determined illuminant does not match the first extreme illuminant, a set of reference point ratios are calculated for the determined illuminant. The reference inversion mask is modified using the calculated set of reference point ratios and the image is corrected with the modified inversion mask.

Abstract: A method is provided for correcting a captured image. The method comprises determining an illuminant for the captured image. When the determined illuminant matches a reference illuminant the image is corrected with a reference inversion mask. When the determined illuminant matches a first extreme illuminant, the reference inversion mask is modified using a first set of reference point ratios that corresponds to the first extreme illuminant and the image is corrected with the modified inversion mask. When the determined illuminant does not match the first extreme illuminant, a set of reference point ratios are calculated for the determined illuminant. The reference inversion mask is modified using the calculated set of reference point ratios and the image is corrected with the modified inversion mask.

Abstract: A method and system for improving the quality of an image in an electronic imaging system is disclosed. The method and system comprise capturing an image frame, capturing a compressed dark frame, decompressing a portion of the compressed dark frame and subtracting the decompressed portion of the compressed dark frame from a corresponding section of the image frame. The steps of decompressing a portion of the compressed dark frame and subtracting the decompressed portion from a corresponding section of the image frame are repeated for additional portions of the compressed dark frame.

Abstract: A method and system for improving the quality of an image obtained by an electronic imaging system is disclosed. The method and system comprise capturing an image frame, capturing a partial dark frame and subtracting the partial dark frame from a corresponding section of the image frame. The steps of capturing a partial dark frame and subtracting the partial dark frame from a corresponding section of the image frame are repeated for additional partial dark frames.

Abstract: A method and device for generating image data are disclosed herein. One embodiment of the method comprises focusing an image of an object onto a two-dimensional photosensor array, wherein an optical element is located between the object and the two-dimensional photosensor array. The optical element is moved, wherein the moving causes the image focused on the two-dimensional photosensor array to move parallel to the two-dimensional photosensor array. Data representative of the image is generated by the two-dimensional photosensor array while the optical element is moving.

Abstract: Disclosed are systems and methods for counteracting lens vignetting. In one embodiment, a system and method pertain to resetting pixels of an image sensor, and reading pixels of the image sensor after they have been reset such that the time between resetting and reading is greater for pixels adjacent edges of the sensor than for pixels adjacent a center of the sensor.

Abstract: A system and related method for compensating for dark current in an image capture device is disclosed. An embodiment of the invention includes an image sensor for capturing a dark image, a memory element for storing the dark image, and logic for assigning a mathematical function to the dark image, where the only variable in the mathematical function is time. The image sensor captures an image, the image including a time of capture indicator, where the time of capture indicator is assigned to the mathematical function. The invention then calculates a dark current value at the time of image capture and subtracts the dark current value from the captured image.

Abstract: A method and system for improving the quality of an image obtained by an electronic imaging system is disclosed. The method and system comprise capturing an image frame, capturing a partial dark frame and subtracting the partial dark frame from a corresponding section of the image frame. The steps of capturing a partial dark frame and subtracting the partial dark frame from a corresponding section of the image frame are repeated for additional partial dark frames.

Abstract: A method and system for improving the quality of an image in an electronic imaging system is disclosed. The method and system comprise capturing an image frame, capturing a compressed dark frame, decompressing a portion of the compressed dark frame and subtracting the decompressed portion of the compressed dark frame from a corresponding section of the image frame. The steps of decompressing a portion of the compressed dark frame and subtracting the decompressed portion from a corresponding section of the image frame are repeated for additional portions of the compressed dark frame.

Abstract: A zoom lens system particularly suited for use with an electronic image sensor includes a first positive lens element group located at a fixed position during a zooming operation, a second moveable negative lens element group, and a third moveable positive lens element group that provides the majority of the magnification change during the zooming operation. The diameter of the first lens element group is relatively large and therefore the surfaces of its glass elements are only spherical. The second and third lens element groups are made of molded plastic lens elements and both contain weak lens elements with aspherical surfaces that primarily correct for aberrations. A conventional aperture stop is positioned between the second lens element group and the third lens element group. Drive mechanisms are used to move the second and third lens element groups back and forth along the optical axis in order to perform a zoom operation.