Abstract:
A system and method that receives and edits image data of an underwater scene in a digital image in order to remove undesirable tints from objects in the scene. In some embodiments, colors near the color of the water itself are protected to leave the water looking blue. Removing undesirable tints without removing the tint of the water itself results in images with more realistic coloring of people and objects in the scene, without eliminating the color cues (e.g., blue water) that indicate that the image is a photograph of an underwater scene.

Description:
BACKGROUND 
     In photography, the color of objects in a photographic image is determined by the intrinsic color of the photographed object and the color of the light or lights that illuminated the object. Lights that illuminate an object are tinted by reflecting off of colored items or passing through a medium that filters out other colors. Photographing things underwater usually results in an overall tinted (often bluish or greenish tint) illumination. The amount of light filtered out, and the colors of the light that are filtered out depend on the depth and the contents of the water (e.g., murky, salt, fresh, etc.). Accordingly, objects that are lit by light passing through water appear incorrectly tinted, while the water itself appears correctly tinted (e.g., tinted the color of water). 
     One type of photographic editing, called “color balancing” or “white balancing” attempts to remove some or all of the effects of the specific light color on the photographed object (e.g., to remove a green or blue tint of a photographed person when the person was illuminated by green or light, such as the light underwater). Various image editing programs apply white balancing techniques to remove the effects of tinted light on an image. Without applying a color balancing technique, the colors of items in the water (e.g., people&#39;s skin) are tinted by the color of the light that filters through the water. However, when previous color balancing techniques are applied to an image taken underwater, or taken of an underwater scene from above the water, the color corrections result in images that do not look as though they were taken underwater. The previous color balancing techniques do not preserve the color of the water. 
     BRIEF SUMMARY 
     Some embodiments provide an application (e.g., an image organizing and editing application) that receives and edits image data of an underwater scene in a digital image in order to remove undesirable tints from objects in the scene. In some embodiments, colors near the color of the water itself are protected to leave the water looking blue. Removing undesirable tints without removing the tint of the water itself results in images with more realistic coloring of people and objects in the scene, without eliminating the color cues (e.g., blue water) that indicate that the image is a photograph of an underwater scene. 
     Each pixel in an image can be represented in a format that includes three chromatic values (e.g., an RGB format). Alternatively, each image can be represented in a luminance/chrominance color system (e.g., a YIQ or YC b C r  color component system) by a luminance value Y and two chrominance values. In some embodiments, an image is converted from one format to the other in order to perform color adjustments in a format best suited for those adjustments. 
     The image editing applications of some embodiments adjust the colors of an image while protecting colors that are close to the color of water in the image by a multi-step process. In some embodiments, the application determines a designated water color for the image. The application performs a gamma adjustment of the image in an RGB format. The application then translates the RGB formatted image into a YIQ formatted image. The application then adjusts the colors in the YIQ formatted image away from the water color. In the course of adjusting the colors in the YIQ format, the application of some embodiments reduces the magnitude of the color adjustment of those pixels with colors close to the designated water color. The application of some embodiments determines a reduction in the magnitude of the color adjustment of some pixel&#39;s colors based on a balance setting (e.g., set by a user or set automatically). The application of some embodiments also reduces or increases the color adjustments of all pixels based on an overall strength setting (e.g., set by a user or set automatically). In the applications of some embodiments, the strength setting applies to all pixels, while the balance setting applies only to pixels closer to the color of water than to the complement of the color of water. The application of some embodiments uses an additional factor to dampen the adjustment depending on the luminance of the individual pixel being adjusted. For example, the application of some embodiments applies smaller adjustments to very bright or very dark pixels than to pixels of mid-range brightness. 
     The application of some embodiments, after adjusting the colors in, e.g., a YIQ colorspace, translates the image back into RGB colorspace. The application then applies an inverse gamma adjustment to the image. Adjusting the color of a pixel in a YIQ colorspace, then performing an inverse gamma correction in RGB colorspace can result in a pixel that is brighter or darker than the original pixel. Making the pixel brighter or darker can be an unwanted side effect of the color adjustment and the inverse gamma transformation. Therefore, in order to keep the adjusted color, but undo the unwanted change to the brightness of the pixel, the application of some embodiments converts the adjusted image and the original image into a luminance-chrominance colorspace (e.g., the YIQ colorspace) and replaces the luminance values of the color adjusted, inverse gamma adjusted image with the corresponding luminance values of the original image. Restoring the original luminance levels results in an image in which the colors have been adjusted, but any changes to the luminance levels of the pixels (e.g., resulting from the non-linear nature of gamma adjustments) will be undone. The application then retranslates the color adjusted YIQ image (with the luminance levels restored) into the RGB colorspace. 
     The preceding Summary is intended to serve as a brief introduction to some embodiments of the invention. It is not meant to be an introduction or overview of all inventive subject matter disclosed in this document. The Detailed Description that follows and the Drawings that are referred to in the Detailed Description will further describe the embodiments described in the Summary as well as other embodiments. Accordingly, to understand all the embodiments described by this document, a full review of the Summary, Detailed Description and the Drawings is needed. Moreover, the claimed subject matters are not to be limited by the illustrative details in the Summary, Detailed Description and the Drawings, but rather are to be defined by the appended claims, because the claimed subject matters can be embodied in other specific forms without departing from the spirit of the subject matters. 
    
    
     
       BRIEF DESCRIPTION OF THE FIGURES 
       The novel features of the invention are set forth in the appended claims. However, for purpose of explanation, several embodiments of the invention are set forth in the following figures. 
         FIG. 1  illustrates the color correction of an underwater image by a program of some embodiments. 
         FIG. 2  illustrates color adjustment of an image with a background color that is a low intensity green color. 
         FIG. 3  conceptually illustrates a process in which an application of some embodiments determines a water color for an underwater image. 
         FIG. 4  conceptually illustrates the determination of some embodiments of a water color for an underwater image. 
         FIG. 5  conceptually illustrates a process of some embodiments for adjusting the colors of an image. 
         FIG. 6  illustrates an image during various stages of a color adjustment process. 
         FIG. 7  conceptually illustrates an example of regions with colors that are closer to an exemplar water color than to its corresponding complement color. 
         FIG. 8  conceptually illustrates the adjustment of a color close to the water color for various balance values. 
         FIG. 9  conceptually illustrates the adjustment of a color close to the complement of the water color for various balance values. 
         FIG. 10  conceptually illustrates the effects of various strength and balance settings on pixel&#39;s colors near the water color and near the complement of the water color. 
         FIG. 11  illustrates a graphical representation of the dampening factor of eqs. (12A) and (12B). 
         FIG. 12  conceptually illustrates software architecture of part of an image editing application of some embodiments. 
         FIG. 13  is an example of an architecture of a mobile computing device. 
         FIG. 14  conceptually illustrates another example of an electronic system with which some embodiments of the invention are implemented. 
     
    
    
     DETAILED DESCRIPTION 
     In the following detailed description of the invention, numerous details, examples, and embodiments of the invention are set forth and described. However, it will be clear and apparent to one skilled in the art that the invention is not limited to be identical to the embodiments set forth and that the invention may be practiced without some of the specific details and examples described. It will be clear to one of ordinary skill in the art that various controls depicted in the figures are examples of controls provided for reasons of clarity. Other embodiments may use other controls while remaining within the scope of the present embodiment. For example, a control depicted herein as a hardware control may be provided as a software icon control in some embodiments, or vice versa. Similarly, the embodiments are not limited to using only the various indicators and icons depicted in the figures. 
     A photograph of an underwater scene typically contains areas that are the color of water (e.g., blue areas in the background) and areas that are not the color of water (e.g., the faces of people in the scene). Generally, even the areas that are not the color of water are somewhat tinted blue by the color of the water because the color of the water tints the light that illuminates the scene. In prior art programs, a color balance tool would remove the tinting from the entire scene. However, this had the effect of greatly reducing or removing the blue color from the water visible in the scene (e.g., the water in the background). The color of the background water would then be more neutral (e.g., somewhat gray). 
     In contrast, some embodiments provide an image editing application that removes the tinting from areas that are not close to the color of water, while applying a reduced adjustment (or no adjustment) to areas that have colors close to the color of water. In some embodiments, the application removes the tinting by shifting the colors of the pixels away from a calculated water color (e.g., a color based on the color of areas in the image, set by a user as the color of water, etc.). In performing color adjustments to a photograph of an underwater scene, the application of some embodiments provides a control to determine whether to fully apply this color correction to the areas that are the color of water, or reduce the color correction effects on those areas. 
       FIG. 1  illustrates the color correction of an underwater image by a program of some embodiments.  FIG. 1  is shown in three stages  101 - 103 . The several colors of the image  110  in the various stages are represented as various patterns in different areas of the image. Legend  150  provides a color key that associates each pattern with a particular color. In stage  101 , the original image  110  displays an underwater scene of a diver  112  in front of a reef  114  and a blue tinted (i.e., shown as blue in legend  150 ) area  116  of the surface of the water. In stage  101 , the diver  112  is shown with skin tinted blue by the ambient light of the scene. The areas of the reef that aren&#39;t dark are predominantly a darker blue than the water, with pink highlights  118  (shown in the pattern identified by legend  150  as pink in stage  101  to contrast with the stronger red color of highlights  118  in later stages). 
     Stage  102  includes an interface of an image editing application  120 , with controls  122 , which include horizontal arrows  124  and vertical arrows  126 . In this stage, the image editing application  120  has adjusted the colors of the image  110 . In the illustrated embodiment, the setting represented by the arrows  124  and  126  is shown by the brightness of the arrow. For example, when a setting is maximized in a particular direction (e.g., to the right) the control arrow in that direction is set to white, while the control arrow in the opposite direction is set to black. One of ordinary skill in the art will understand that other embodiments use other indicators of the state of the setting (e.g., sliders, etc.) and that some embodiments do not display an overt indicator of the setting. Here, the control  122  is set with the horizontal control arrows  124  set all the way to the right (i.e., the right arrow is white and the left arrow is black) and the vertical control arrows  126  set all the way at the top. In this embodiment, this setting of the horizontal arrows  124  commands the application to preserve colors near the color of the water, while adjusting the colors of the image. The setting of the vertical arrows  126  commands the application to set the strength of the color adjustments to maximum (within the limitations imposed by the color adjustment system of the application  120 ). The diver  112  in the image  110  has colors that are mostly different from the color of water. Accordingly, the application has shifted the colors of the diver (e.g., skin tones) away from the blue tinted colors of the original image. The shift makes the diver  112  stand out, with more vibrant skin tones than the previous blue tinted skin tones. The red highlights  118  in the reef  114  also stand out more clearly in stage  102  with a more vibrant red color. The blue areas of the image remain blue because the controls  122  are set to preserve colors near the color of the water. 
     In stage  103 , the vertical arrows  126  of controls  122  are still set to maximum. However, the horizontal arrows are set all the way to the left (i.e., the left arrow is white and the right arrow is black), commanding the image editing application  120  not to protect colors near the color of the water while adjusting the colors of the image. Therefore, in contrast to the image  110  in stage  102 , in stage  103  the image editing application  120  has adjusted the colors of the image  110  without protecting the color of the water. Accordingly, the colors of the reef  114  and the area  116  have been adjusted to redder colors (i.e., purple for reef  114  and red for area  116  as shown in legend  150 ). 
     In some embodiments, the color of the water is determined from an average value of the colors of a set of pixels in the image (e.g., the pixels in a user selected area, an automatically selected area, or all the pixels in the image). The average color of the water is usually a color with blue as the predominant color component (i.e., the water has a bluish tint). However, in some underwater images, the background color has a greenish tint rather than a bluish tint. A green tint to the water may be undesirable as compared to blue. Accordingly, in some embodiments, the application adjusts the image from green toward a more neutral color. Some embodiments perform color adjustments in a YIQ colorspace. In the YIQ colorspace, the −I −Q direction is the direction of green. Therefore, the application shifts the image in the opposite color direction from green (i.e., +I +Q, toward magenta). 
     In  FIG. 1 , the average color of image  110  is an intense blue. The application shifted the water color slightly toward +I and +Q, but the effect was small relative to the intensity of the color of the background and the direction of the color shift was not directly away from the blue direction in colorspace. Therefore, the background remained blue. As mentioned above, in some underwater images, the average color has a greenish tint rather than a bluish tint. Furthermore, in some images the tint is slight rather than intense. The color adjuster changes the colors of such images more visibly as the small shift toward +I and +Q is relatively larger compared to the original color intensity and is directly opposed to the original color (green, with a value of −I and −Q). 
       FIG. 2  illustrates color adjustment of an image  200  with a background color that is a low intensity green color. The figure is shown in three stages  201 - 203  with legend  250 . Legend  250  provides a color key that associates each pattern with a particular color. 
     In stage  201 , the original image  200  has a greenish tint. In stage  202 , the horizontal arrows  124  are set all the way to the right (i.e., the right arrow is white and the left arrow is black). Therefore, the image editing application  120  has adjusted the colors of the image while protecting the pixels that have colors close to the color of the water (as adjusted by the shift away from green). Accordingly, the sand  220  in image  200  in stage  202  is a beige color rather than the greenish color of stage  201 . In stage  203 , the horizontal arrows  124  are set all the way to the left (i.e., the left arrow is white and the right arrow is black). Therefore, image editing application  120  has adjusted the colors of the image while not protecting the pixels that have colors close to the color of the water (as adjusted by the shift away from green). Accordingly, the colors of the image including the sand have been significantly shifted toward magenta (away from green) and the image  200  as a whole, in stage  203 , has a magenta tint (e.g., the sand  220  has turned pink). 
     The shift in color of the background sand  220  from stage  201  to stage  202  is more significant than the shift in color of the blue tinted water surface  116  in stages  101  and  102  of  FIG. 1  because of the shift of the whole image in the +I and +Q direction. The shift is also more significant because of the lower starting intensity of the greenish tint of the background sand  220  in  FIG. 2  as compared to the blue tint of the surface  116  in  FIG. 1 . 
     Section I, below, describes color adjustments of some embodiments. Then section II describes a software architecture of some embodiments. Section III describes a mobile device on which image editing applications of some embodiments run. Section IV describes another computing device on which the image editing applications of some embodiments run. 
     I. Color Adjustment 
     A. Calculating Water Color 
     The application of some embodiments determines a “water color” based on a modified average of the color of the pixels in an area of the image. This method of determining the color of water in an image is based on an assumption that the colors of the image would average out to a neutral gray unless there were some tint to all the colors of the image caused by the light that illuminated the scene captured in the image. The light in an underwater scene is filtered through the water and is tinted a blue to green color by the water. Accordingly, the average colors of the pixels in the image represent an initial value of the color of the water. The average color is then modified for aesthetic reasons. This modified average is referred to herein as the “color of water” or the “water color”. The applications of some embodiments translate the modified average into a different color space and selectively move the colors of the image away from the determined color of water. 
     In some embodiments, the area used to determine the water color is an area selected by a user. In other embodiments, the area used is determined automatically by the application (e.g., the entire area of the image). In some embodiments, the average is determined in an RGB colorspace and then modified and converted to a YIQ colorspace. The color of the water is then used to adjust the colors of the image. 
       FIG. 3  conceptually illustrates a process  300  in which an application of some embodiments determines a water color for an underwater image.  FIG. 3  will be described with respect to  FIG. 4 .  FIG. 4  conceptually illustrates the effects of process  300  through five stages  401 - 405 . 
     The process  300  determines (at  305 ) an average value of the color component values of the pixels in an image. That is, one average value is determined for red, another for blue, and a third for green. In some embodiments, the average is the arithmetic mean of the values. In some embodiments, the R, G, and B values are scaled from 0 to 1 before the averages are determined. In some embodiments, the values are determined mathematically and no visible graph is displayed. In  FIG. 4 , stage  401 , the red (R ave ), green (G ave ), and blue (B ave ) average color values are displayed on a 3-axis graph  410  as point  415 . 
     The process  300  then determines (at  310 ) whether the average pixel color is too dark. When the average pixel color is too dark (e.g., the sum of the average R, G, and B values is below a particular threshold) then the process  300  rescales (at  315 ) the average color values. In some embodiments, the threshold is ½ of the maximum possible value for one color component and therefore ⅙ of the maximum possible value of the sums of the color component values. In some embodiments, the R, G, and B values are rescaled with eq. (1A)-(1C) if the sum of the averages is below the threshold. However, the average values in such embodiments are not rescaled if the sum of the averages is at or above the threshold.
 
 R   water =(−4*( R   ave   +G   ave   +B   ave )+3)* R   ave   (1A)
 
 G   water =(−4*( R   ave   +G   ave   +B   ave )+3)* G   ave   (1B)
 
 B   water =(−4*( R   ave   +G   ave   +B   ave )+3)* B   ave   (1C)
 
     In eq. (1A)-(1C): R water  is the scaled value of the average R value of the pixels in the selected area. R ave  is the actual average R value of the pixels in the selected area. G water  is the scaled value of the average G value of the pixels in the selected area. G ave  is the actual average G value of the pixels in the selected area. B water  is the scaled value of the average B value of the pixels in the selected area. B ave  is the actual average B value of the pixels in the selected area. 
     In  FIG. 4 , in stage  401 , the sum of the R, G, and B values of the selected area of the image are below the threshold. Accordingly, in stage  402 , the rescaled values (R water , G water , and B water ) are shown on the 3-axis graph  420  as point  425 . Point  425  has slightly larger R, G, and B values than R ave , G ave , and B ave  of stage  401 . When the process  300  (of  FIG. 3 ) determines (at  310 ) that the average color is not too dark, the process  300  skips operation  315  and moves on to operation  320 . 
     The applications of some embodiments make color adjustments of the image in a YIQ colorspace. Therefore, the process  300  of  FIG. 3  further translates (at  320 ) the water color into the YIQ colorspace in order to maintain consistency with an image which has been translated into YIQ colorspace. In some embodiments, the color adjustments are made to the chromatic components (I and Q) but not to the Y component. Accordingly the graphs in stages  403 - 405  of  FIG. 4  show only I and Q axes. In stage  403 , the 2-axis graph  430  shows the I and Q values, represented by point  435 , translated from the R, G, and B values, represented by point  425 , from graph  420  of stage  402 . 
     In some embodiments, one or both of the I and Q values are calculated in a non-traditional, non-linear manner. For example, the applications of some embodiments use eqs. (2A) and (2B) to calculate the I and Q values.
 
 I= 0.596 R− 0.2755 G− 0.321 B   (2A)
 
 Q= 0.212 R   0.5 −0.523 G   0.5 +0.311 B   0.5   (2B)
 
     In eqs. (2A)-(2B), R is the rescaled value of R ave . G is the rescaled value of G ave . B is the rescaled value of B ave . One of ordinary skill in the art will recognize eq. (2A) as a slightly modified version of the standard conversion function from RGB to I. Eq. (2B) is also a slightly modified conversion, but with a gamma correction (using a gamma value of 0.5) applied to the RGB values before using the RGB values to calculate the Q value. In other embodiments, different gamma adjustments (e.g., ¼, ⅛, or 1/16) are made to the R, G, and B values used to calculate I, Q, or both. 
     As described above with respect to  FIG. 2 , a green tinge to an image may be considered undesirable. Accordingly, in some embodiments, the colors of the image are adjusted away from green. The process  300  of  FIG. 3  performs this adjustment by shifting (at  325 ) the water color toward the −I, −Q direction (i.e., toward green). The application of some embodiments shifts the image colors away from the color of water. Therefore, when the application adjusts the water color toward green the result is a shift of the post-adjustment image colors away from green. Graph  440  in stage  404  of  FIG. 4  illustrates such a shift. The shifted water color value, represented by point  445 , has moved toward the lower left (green) corner of graph  440  relative to the converted I-Q values, represented by point  435  of the water color in graph  430  in stage  403 . 
     Some embodiments perform both the conversion to YIQ values and the shift of the water color toward green in one mathematical step. That is, in some embodiments, the conversions from RGB to YIQ values are performed using eqs. (3A)-(3B), which include a slight shift toward −Q and −I.
 
 I= 0.596 R− 0.2755 G− 0.321 B− 0.05  (3A)
 
 Q= 0.212 R   0.5 −0.523 G   0.5 +0.311 B   0.5 −0.05  (3B)
 
     In eqs. (2A)-(2B), R is the rescaled value of R ave . G is the rescaled value of G ave . B is the rescaled value of B ave . 
     In some embodiments, if the calculated Q value is too negative (e.g., more than a threshold distance below zero) the I value is decreased. The process  300  of  FIG. 3  determines (at  330 ) whether the Q value is too negative (e.g., less than a threshold negative value such as −0.1). When the Q value is too negative, the process  300  decreases (at  335 ) the color value&#39;s I component. When the Q value is not too negative, the process  300  ends without changing the I value. In some embodiments, the process  300  uses eq. (4A) to adjust the I value and eq. (4B) if the Q value is not too negative.
 
if  Q&lt;− 0.1 then  I   adj   =I+ 2( Q+ 0.1)  (4A)
 
if  Q&gt;− 0.1 then  I   adj   =I   (4B)
 
     In eqs. (4A) and (4B), I is the unadjusted I value and I adj  is the I value after adjustment (or after adjustment is determined to be unnecessary). Graph  450  in stage  405  of  FIG. 4  shows the I and Q values, represented by point  455 , after such an adjustment. The process  300  of  FIG. 3  then ends. 
     In some embodiments, the above described calculations and adjustments are used to automatically determine a color of water for an image. In some embodiments, either as an alternative option or instead of the automatic calculation, the image editing application provides a set of controls that allows a user to determine a color to use as the water color. 
     B. Adjusting Image Colors 
     Given a water color as a basis for color adjustments to the pixel of an image, the image editing application of some embodiments is able to adjust the colors while protecting the colors of the image. The applications of some embodiments include settings to determine the strength of the color adjustment and the balance between protecting and not protecting colors near the color of water. 
       FIG. 5  conceptually illustrates a process  500  of some embodiments for adjusting the colors of an image (e.g., an image taken underwater). The process  500  is described with references to  FIGS. 4 and 6-11 .  FIGS. 6-11  are described below as they become relevant to the process  500 . The process  500  determines (at  505 ) a water color of an image (e.g., as described with respect to  FIG. 4 , above). The application of some embodiments uses the determined water color to adjust the colors of the image. 
     The process  500  performs (at  510 ) a gamma adjustment on the image.  FIG. 6  illustrates an image during various stages of a color adjustment process. The figure includes versions of the image before and after an initial gamma adjustment and a later inverse gamma adjustment. The gamma adjustment of some embodiments is performed by raising each component value of a pixel to a low power (e.g., ¼, ⅙, or ⅛). In some embodiments, the component values are between 0 and 1 inclusive, with 1 being the brightest and 0 being the dimmest. Raising the component values to a power less than 1 increases the component values and, therefore, brightens the pixels. 
     The first two stages  601  and  602  of  FIG. 6  show such a gamma adjustment. In stage  601 , an original image  610  is shown. In stage  602 , a gamma adjusted image  620  is shown. The gamma adjusted image  620  is lighter than the original image because a gamma adjustment by a low power increases each of the R, G, and B color values between 0 and 1. In the figure, the lightening of the image as a result of the gamma adjustment from stage  601  to stage  602  is represented by a reduction in the density of the patterns representing various colors in the image. In the gamma adjusted image, the color contrast of pixels with very low color component values is expanded (and the component value increased), while the color contrast of pixels with higher color component values is compressed (and concentrated near the top of the scale). The color adjustments between stages  602  and  603  are more complex and will be described with respect to operations  515 - 545  of  FIG. 5 . In  FIG. 6 , the color adjustment from stage  602  to stage  603  is represented by a change of patterns in the image. 
     Stages  603  to  604  illustrate a gamma adjustment of the color adjusted image  630 . The gamma adjustment is the inverse operation of the original gamma adjustment of the image  610 . The inverse gamma adjustment of some embodiments applies an exponent of greater than 1 to the color values of each pixel. In some embodiments, the component values are between 0 and 1 inclusive, with 1 being the brightest and 0 being the dimmest. Raising the component values to a power greater than 1 decreases the component values and, therefore, darkens the pixels. In  FIG. 6 , the darkening of the image as a result of the gamma adjustment from stage  603  to stage  604  is represented by a reduction in the density of the patterns representing various colors in the image. 
     After the initial gamma adjustment of the image, the process  500  of  FIG. 5  then converts (at  515 ) the image into a YIQ colorspace. In some embodiments, the water color conversion and the image conversion are done into some other colorspace with at least one luminance value and two chrominance values (e.g., YUV colorspace, etc.). 
     The process  500  receives (at  520 ) a balance setting that determines how much to protect colors near the determined water color from color adjustments and a strength setting that provides an overall strength for the color adjustment. In some embodiments, the process determines the balance and/or strength settings automatically. In other embodiments, the process receives the balance and/or strength settings from a user. 
     The process  500  then selects (at  525 ) a pixel of the image. The process  500  determines (at  530 ) whether the color of the selected pixel is closer to the previously determined water color or to the complement of the water color. In some embodiments, the determination is made using eqs. (5A)-(5B).
 
waterchroma=(( I−I   water ) 2 +( Q−Q   water ) 2 ) 0.5   (5A)
 
antichroma=(( I+I   water ) 2 +( Q+Q   water ) 2 ) 0.5   (5B)
 
     In eqs. (5A) and (5B), I water  represents the I component of the determined color of the water. Q water  represents the Q component of the determined color of the water. I represents the I component of the pixel&#39;s color. Q represents the Q component of the pixel&#39;s color. Waterchroma represents the distance (in colorspace) of the chromatic components of the pixel (e.g., I and Q) from the chromatic components of the water color. Antichroma represents the distance (in colorspace) of the chromatic components of the pixel (e.g., I and Q) from the chromatic components of the complement of the water color. When antichroma is smaller than waterchroma, the pixel chromatic components are closer to the complement of the water color than to the water color. When waterchroma is smaller than antichroma, the pixel chromatic components are closer to the water color than to the complement of the water color. 
       FIG. 7  conceptually illustrates an example of regions that have colors closer to an exemplar water color than to its corresponding complement color. In this figure, graph  700  displays water color  710 , complement  720  of the water color, and line  730 . Water color  710  represents the I and Q values of the determined water color. Complement  720  represents the I and Q values of the complementary color from the water color. Line  730  represents all the colors that are equidistant from both the water color  710  and the complement  720 . The applications of some embodiments adjust the colors of pixels on both sides of the line  730  and on the line  730 . However, when the applications of some embodiments determine magnitudes for the color adjustments of pixels with colors on the water color  710  side of the line  730 , these magnitudes are affected by the balance setting. In contrast, when these applications determine magnitudes for the color adjustments of pixels with colors on the complement  720  side of the line  730  or on the line  730 , these magnitudes are not affected by the balance setting. 
     When the process  500  of  FIG. 5  determines (at  530 ) that the pixel&#39;s color is closer to the water color than to the complement of the water color, the process  500  adjusts (at  535 ) the pixel&#39;s color based on the proximity of the pixel&#39;s color to the water color and/or the pixel&#39;s color&#39;s proximity to the complement of the water color. In some embodiments, when the balance is set fully to protect the water color, the magnitude of the color adjustment will be based on the distance of the pixel&#39;s color from the water color, but not on the distance from the pixel&#39;s color to the complement of the water color. In contrast, when the balance is set fully to not protect the water color, the magnitude of the color adjustment will not be based on the distance of the pixel&#39;s color from the water color, but will be based on the distance from the pixel&#39;s color to the complement of the water color. When the balance setting is between the extremes, the magnitude of the color adjustment is based on a weighted average of the distance of the pixel&#39;s color to each of the water color and the complement of the water color. The process of some embodiments uses eqs. (6) and (7) to provide a multiplier for the adjustment.
 
chroma=waterchroma*balance+(1−balance)*antichroma  (6)
 
shift=chroma 2 *strength  (7)
 
     In eq. (6), waterchroma is the distance from the pixel&#39;s color to the water color. Antichroma is the distance from the pixel&#39;s color to the complement of the water color. Balance determines the weight for a weighted average of waterchroma and antichroma. In eqs. (6) and (7) chroma is the weighted average of the waterchroma and antichroma values. In eq. (7), shift is a multiplier used in the color adjustment of the pixel. Strength determines an overall strength of the color adjustment (the effects of the strength setting are shown in  FIG. 10 , described below). 
     Once the multiplier has been determined, some embodiments use eqs. (8A) and (8B) to determine the adjusted color values for the pixel.
 
 I   adj   =I−I   water *shift  (8A)
 
 Q   adj   =Q−Q   water *shift  (8B)
 
     In eqs. (8A) and (8B), I water  represents the I component of the determined color of the water. Q water  represents the Q component of the determined color of the water. I represents the I component of the pixel&#39;s color. Q represents the Q component of the pixel&#39;s color. I adj  is the I component of the adjusted pixel&#39;s color. Q adj  is the Q component of the adjusted pixel&#39;s color. 
       FIG. 8  conceptually illustrates the adjustment of a color close to the water color for various balance values. The figure includes multiple graphs  801 - 806 , which will be individually described. In some embodiments, the graphs are conceptual of the calculations being performed and no such graph is actually displayed to the user. Graph  801  shows the location in I-Q space of the color of water  810  (e.g., as determined by the process described with respect to  FIG. 4 ) and the complement  812  of the color of water. In some embodiments, the complement of the water color is determined by reversing the sign of the I and Q values of the water color. In some embodiments, the complement of the water color is not directly calculated and is represented in calculations by, e.g., adding the component values of the water color rather than subtracting the component values of the complement of the water color. Graph  802  shows an exemplar starting pixel&#39;s color  820 , waterchroma distance  822 , and antichroma distance  824 . Waterchroma distance  822  is smaller than antichroma distance  824 ; therefore a balance setting will affect the color adjustment of this starting pixel&#39;s color  820 . 
     Graph  803  shows the direction  830  of the complement of the water color. In some embodiments, the color adjustments of each pixel&#39;s color are in that direction  830 . Graphs  804 ,  805 , and  806  show the color adjustment of the starting pixel&#39;s color  820  to ending pixel&#39;s colors  840 ,  850 , and  860 , respectively. For graph  804 , the balance setting  842  is 1. Therefore, the adjusted pixel&#39;s color depends on the (small) distance from the starting pixel&#39;s color  820  to the water color  810  and not on the (large) distance from the starting pixel&#39;s color  820  to the complement  812  of the water color. Accordingly, the adjustment is small when the balance is high. For graph  805 , the balance setting  852  is 0.5. Therefore, the adjusted pixel&#39;s color depends equally on the (small) distance from the starting pixel&#39;s color  820  to the water color  810  and on the (large) distance from the starting pixel&#39;s color  820  to the complement  812  of the water color. Accordingly, the adjustment is intermediate when the balance is intermediate. For graph  806 , the balance setting  862  is 0. Therefore, the adjusted pixel&#39;s color does not depend on the (small) distance from the starting pixel&#39;s color  820  to the water color  810 , but does depend on the (large) distance from the starting pixel&#39;s color  820  to the complement  812  of the water color. Accordingly, the adjustment is large when the balance is low. 
     When the process  500  of  FIG. 5  determines (at  530 ) that the pixel&#39;s color is farther from the water color than the complement of the water color, the process  500  adjusts (at  540 ) the pixel&#39;s color based on the proximity of the pixel&#39;s color to the complement of the water color. In some embodiments, the balance setting does not affect the adjustment of such pixels. The process of some embodiments uses eqs. (9) and (10) to provide a multiplier for the adjustment.
 
chroma=antichroma  (9)
 
shift=chroma 2 *strength  (10)
 
     In eq. (9), antichroma is the distance from the pixel&#39;s color to the complement of the water color. In eqs. (9) and (10) chroma is equal to the antichroma value. In eq. (10), shift is a multiplier used in the color adjustment of the pixel. Strength determines an overall strength of the color adjustment (the effects of the strength setting are shown in  FIG. 10 , described below). 
     Once the multiplier has been determined, some embodiments use the same eqs. (8A) and (8B) to determine the adjusted color values for a pixel closer to the complement as is used to determine the adjusted color value for a pixel closer to the water color.
 
 I   adj   =I−I   water *shift  (8A)
 
 Q   adj   =Q−Q   water *shift  (8B)
 
     In eqs. (8A) and (8B), I water  represents the I component of the determined color of the water. Q water  represents the Q component of the determined color of the water. I represents the I component of the pixel&#39;s color. Q represents the Q component of the pixel&#39;s color. I adj  is the I component of the adjusted pixel&#39;s color. Q adj  is the Q component of the adjusted pixel&#39;s color. 
       FIG. 9  conceptually illustrates the adjustment of a color close to the complement of the water color for various balance values in some embodiments. The balance values in such embodiments have no effect because the pixel&#39;s color is closer to the complement of the water color than to the water color (e.g., because equations (9) and (10), which does not depend on the balance value are used to calculate the shift value, rather than equations (6) and (7), which do depend on the balance value). In  FIG. 9  multiple balance values are shown to demonstrate the effects (or lack thereof) of various balance values on a pixel with a color closer to the complement of water color. The lack of effect in  FIG. 9  contrasts with the effects (in  FIG. 8 ) of the same set of balance values on a pixel color that is closer to the water color than to the complement of the water color.  FIG. 9  includes multiple graphs  901 - 906 , which will be individually described. In some embodiments, the graphs are conceptual of the calculations being performed and no such graph is actually displayed to the user. Graph  901  shows the location in I-Q space of the color of water  910  (e.g., as determined by the process described with respect to  FIG. 4 ) and the complement  912  of the color of water. In some embodiments, the complement of the water color is determined by reversing the sign of the I and Q values of the water color. In some embodiments, the complement of the water color is not directly calculated and is represented in calculations by, e.g., adding the component values of the water color rather than subtracting the component values of the complement of the water color. Graph  902  shows an exemplar starting pixel&#39;s color  920 , waterchroma distance  922 , and antichroma distance  924 . Waterchroma distance  922  is larger than antichroma distance  924 ; therefore a balance setting will not affect the color adjustment of this starting pixel&#39;s color  920 . 
     Graph  903  shows the direction  930  of the complement  912  of the water color. In some embodiments, the color adjustments of each pixel&#39;s color are in that direction  930 . Graphs  904 ,  905 , and  906  show the color adjustment of the starting pixel&#39;s color  920  to ending pixel&#39;s colors  940 ,  950 , and  960 , respectively. For graph  904 , the balance setting  942  is 1. For graph  905 , the balance setting  952  is 0.5. For graph  906 , the balance setting  962  is 0. However, the adjusted pixel&#39;s color does not depend on the balance value and therefore is identical regardless of the balance setting. The magnitude of the adjustment is small because the distance from the complement  912  of the water color is small. 
     In some embodiments, regardless of whether a pixel is closer to the water color or closer to the complement of the water color, the strength setting affects the magnitude of the color adjustment.  FIG. 10  conceptually illustrates the effects of various strength and balance settings on pixel&#39;s colors near the water color and near the complement of the water color. The figure includes graphs  1001 - 1006 . Each graph includes two starting color points  1010  and  1012 . Color point  1010  is close to a water color (not shown). Color point  1012  is close to the complement (not shown) of the water color. In graphs  1001 - 1004 , the colors represented by the starting color points  1010  and  1012  change depending on the location of the starting color points, the balance setting, and the strength setting. 
     Graph  1001  shows the adjustments of the color points  1010  and  1012  when the strength is set to 1 (at the highest strength available) and the balance is set to 1 (highest level of protection for colors closer to the water color than the complement of the water color). Regardless of the balance setting, the adjustment of the color point  1012  is determined by its proximity to the complement of the water color. The color point  1012  is close to the complement (not shown) of the water color, therefore the adjustment is small. In some embodiments, the small adjustment of the colors close to the complement of the water color reduces the incidence of oversaturation of the adjusted colors. Under the illustrated balance setting, the adjustment of the color point  1010  is determined by its proximity to the water color. The color point  1010  is close to the water color (not shown), therefore the adjustment is small. In some embodiments, the small adjustment of the colors close to the water color allows the image to maintain water colors in those areas that were already a color close to the water color (e.g., the water). However, in those areas that are colors other than the water color, but are tinted by the effects of the water on the lighting of the scene, the color adjustment is greater. 
     In contrast to graph  1001 , graph  1002  shows the adjustments of the color points  1010  and  1012  when the strength is set to 1 (at the highest strength available) and the balance is set to 0 (no protection for colors closer to the water color than the complement of the water color). As mentioned above, regardless of the balance setting, the adjustment of the color point  1012  is determined by its proximity to the complement of the water color. The color point  1012  is close to the complement (not shown) of the water color, therefore the adjustment is small. Under the illustrated balance setting, the adjustment of the color point  1010  is also determined by its proximity to the complement of the water color. The color point  1010  is far from the complement of the water color (not shown), therefore the adjustment is large. In some embodiments, a large adjustment of the colors close to the water color prevents the image from maintaining water colors in those areas that (in the original image) are already a color close to the water color (e.g., the water in the image). Therefore, the colors close to the water color shift even more than the colors near the complement of the water color. 
     In graphs  1003  and  1004 , the balance settings are the same as for graphs  1001  and  1002  respectively, but the strength settings are half (0.5) of what they are in graphs  1001  and  1002 . Accordingly, all adjustments are reduced to half of what they are in the corresponding graphs  1001  and  1002 . Finally, in graphs  1005  and  1006 , the strength settings are reduced to zero. Therefore the adjustments are also reduced to zero regardless of the proximity of the color points  1010  and  1012  to the water color or the complement of the water color. 
     In some embodiments, the strength setting is determined automatically. In some such embodiments, the applications use eq. (11) to determine an automatic setting for the strength. In some embodiments, the automatic setting is provided as a default setting and the application provides a control (e.g., a slider or a pair of arrows) that allows the user to change the strength setting.
 
strength=(4*( I   water   *I   water   +Q   water   *Q   water )) −1   (11)
 
     In eq. (11), I water  represents the I component of the determined color of the water. Q water  represents the Q component of the determined color of the water. Strength represents the automatically determined strength setting. 
     In the previously described factors relating to color adjustment, the luminance value of the pixels being adjusted has not been a factor. However, in some embodiments, the process  500  of  FIG. 5  sometimes adjusts (at  535  or  540 ) the colors of pixels that are either very bright, or very dark. In some cases, large color changes in dark areas or bright areas of an image are undesirable. For example, it is undesirable to turn the shadows or highlights of an image (e.g., blacks, bubbles, specular reflections, etc.) to the complement of the water color (e.g., pink). Accordingly, the process  500  of some embodiments reduces the magnitude of the color adjustment based on the luminance (e.g., Y component value) of the pixel that the process  500  is adjusting. 
     In some embodiments, eqs. (12A), (12B), (13A), and (13B) are used to reduce the magnitude of the adjustment.
 
If  Y&lt; 0.9 then damp= Y   (12A)
 
If  Y&gt; 0.9 then damp=9−9* Y   (12B)
 
 I   adj   =I−I   water *shift*damp  (13A)
 
 Q   adj   =Q−Q   water *shift*damp  (13B)
 
     In eqs. (12A), (12B), (13A), and (13B), damp is an additional factor that reduces the magnitude of color adjustments. Y is the luminance of the pixel. I water  represents the I component of the determined color of the water. Q water  represents the Q component of the determined color of the water. I represents the I component of the pixel&#39;s color. Q represents the Q component of the pixel&#39;s color. I adj  is the I component of the adjusted pixel&#39;s color. Q adj  is the Q component of the adjusted pixel&#39;s color. 
       FIG. 11  illustrates a graphical representation of the dampening factor of eqs. (12A) and (12B). The figure includes graph  1100  which shows a plot of luminance value vs. dampening factor. When the luminance of a pixel is low, the adjustment amount is multiplied by a small number. When the luminance of a pixel is higher, but under 0.9 the adjustment amount is increased. When the luminance of the pixel is at 0.9, the adjustment amount is at a maximum. When the luminance of the pixel is greater than 0.9, the adjustment amount decreases rapidly with luminance level until, at a luminance of 1, the adjustment is canceled entirely. Eqs. (12A) and (12B) represent a specific dampening function of some embodiments. However, one of ordinary skill in the art will understand that in other embodiments, other dampening functions are used. While in still other embodiments, no dampening function is used. 
     After the pixel is color adjusted (at  535  or  540 ), the process  500  of  FIG. 5  then determines (at  545 ) whether the most recently adjusted pixel was the last pixel in the image to be adjusted. When the pixel was not the last pixel in the image, the process  500  returns to operation  525  to select another pixel for adjustment. When the pixel was the last pixel to be adjusted, the process  500  converts (at  550 ) the image from the colorspace in which the adjustment was performed (e.g., the YIQ colorspace) to the RGB color space. The process  500  then applies (at  555 ) a gamma adjustment that is the inverse of the previous gamma adjustment (e.g., if the component values were previously raised to the power of ⅛ then in this operation they are raised to the power of 8). 
     In some embodiments, in order to ensure that the sequence of gamma correction-color correction-inverse gamma correction does not change the luminance levels of any of the pixels in the image, the process  500  restores (at  560 ) the original luminance values of the image by translating both the image that has been gamma adjusted, color adjusted, and inverse gamma adjusted and the uncorrected image (i.e., without gamma corrections and color adjustments applied) into YIQ colorspace. The process  500  replaces the Y component values of each of the pixels in the adjusted image with the Y component values of the corresponding pixels in the unadjusted image. The process  500  then ends. 
     II. Software Architecture 
       FIG. 12  conceptually illustrates software architecture  1200  of part of an image editing application of some embodiments. The figure illustrates the part of the architecture that is concerned with adjusting the colors of an underwater image. One of ordinary skill in the art will understand that the image editing applications of some embodiments include other modules not covered in this figure. The figure includes color calculator  1210 , underwater image adjuster  1220 , user interface  1230 , and image storage  1240 . The color calculator  1210  of some embodiments performs the calculations that determine a color of water. The color calculator  1210  of some embodiments retrieves an image from image storage  1240  and uses equations (1A)-(4B) to calculate a color of water for the image. In some embodiments, the color calculator  1210  calculates I and Q components of a color of water in a YIQ colorspace. In some embodiments, the color calculator  1210  also determines a complement of the color of water. The color calculator then sends the color of water to the underwater image adjuster  1220 . 
     The underwater image adjuster  1220  of some embodiments uses the calculated color of water (e.g., received from color calculator  1210 ) and strength and balance settings (e.g., received from the user interface  1230 ) to determine adjusted color values for each pixel in an image (e.g., received from image storage  1240 ). In some embodiments, the underwater image adjuster  1220  uses equations (5A)-(13B) to determine an adjusted color for each pixel. The underwater image adjuster  1220  of some embodiments then stores the adjusted image in the image storage  1240 . 
     The user interface  1230  of some embodiments receives a balance and strength setting from a user and passes the balance and strength settings to the underwater image adjuster. In some embodiments, the user interface  1230  presents the user with controls such as controls  122  of  FIG. 1  and determines the strength and balance settings based on a user&#39;s manipulation of the controls  122 . 
     The image storage  1240  of some embodiments stores an original image (e.g., provided by a user) which can then be modified by the underwater image adjuster  1220  and/or other image adjustment modules (not shown) of the image editing application. In some embodiments, the image storage  1240  stores both the original image and the adjusted image separately (e.g., so that a user can undo an adjustment). 
     The software architecture diagram of  FIG. 12  is provided to conceptually illustrate some embodiments. One of ordinary skill in the art will realize that some embodiments use different modular setups that may combine multiple functions into one module though the figure shows multiple modules, and/or may split up functions that the figure ascribes to a single module into multiple modules, and/or may recombine the split up functions in various modules. Furthermore different connections may be made among these modules. For example, in some embodiments the color calculator  1210  and the underwater image adjuster  1220  are combined into a single module. 
     III. Mobile Device 
     The image organizing, editing, and viewing applications of some embodiments operate on mobile devices, such as smartphones (e.g., iPhones®) and tablets (e.g., iPads®).  FIG. 13  is an example of an architecture  1300  of such a mobile computing device. Examples of mobile computing devices include smartphones, tablets, laptops, etc. As shown, the mobile computing device  1300  includes one or more processing units  1305 , a memory interface  1310  and a peripherals interface  1315 . 
     The peripherals interface  1315  is coupled to various sensors and subsystems, including a camera subsystem  1320 , a wireless communication subsystem(s)  1325 , an audio subsystem  1330 , an I/O subsystem  1335 , etc. The peripherals interface  1315  enables communication between the processing units  1305  and various peripherals. For example, an orientation sensor  1345  (e.g., a gyroscope) and an acceleration sensor  1350  (e.g., an accelerometer) is coupled to the peripherals interface  1315  to facilitate orientation and acceleration functions. 
     The camera subsystem  1320  is coupled to one or more optical sensors  1340  (e.g., a charged coupled device (CCD) optical sensor, a complementary metal-oxide-semiconductor (CMOS) optical sensor, etc.). The camera subsystem  1320  coupled with the optical sensors  1340  facilitates camera functions, such as image and/or video data capturing. The wireless communication subsystem  1325  serves to facilitate communication functions. In some embodiments, the wireless communication subsystem  1325  includes radio frequency receivers and transmitters, and optical receivers and transmitters (not shown in  FIG. 13 ). These receivers and transmitters of some embodiments are implemented to operate over one or more communication networks such as a GSM network, a Wi-Fi network, a Bluetooth network, etc. The audio subsystem  1330  is coupled to a speaker to output audio (e.g., to output voice navigation instructions). Additionally, the audio subsystem  1330  is coupled to a microphone to facilitate voice-enabled functions, such as voice recognition (e.g., for searching), digital recording, etc. 
     The I/O subsystem  1335  involves the transfer between input/output peripheral devices, such as a display, a touch screen, etc., and the data bus of the processing units  1305  through the peripherals interface  1315 . The I/O subsystem  1335  includes a touch-screen controller  1355  and other input controllers  1360  to facilitate the transfer between input/output peripheral devices and the data bus of the processing units  1305 . As shown, the touch-screen controller  1355  is coupled to a touch screen  1365 . The touch-screen controller  1355  detects contact and movement on the touch screen  1365  using any of multiple touch sensitivity technologies. The other input controllers  1360  are coupled to other input/control devices, such as one or more buttons. Some embodiments include a near-touch sensitive screen and a corresponding controller that can detect near-touch interactions instead of or in addition to touch interactions. 
     The memory interface  1310  is coupled to memory  1370 . In some embodiments, the memory  1370  includes volatile memory (e.g., high-speed random access memory), non-volatile memory (e.g., flash memory), a combination of volatile and non-volatile memory, and/or any other type of memory. As illustrated in  FIG. 13 , the memory  1370  stores an operating system (OS)  1372 . The OS  1372  includes instructions for handling basic system services and for performing hardware dependent tasks. 
     The memory  1370  also includes communication instructions  1374  to facilitate communicating with one or more additional devices; graphical user interface instructions  1376  to facilitate graphic user interface processing; image processing instructions  1378  to facilitate image-related processing and functions; input processing instructions  1380  to facilitate input-related (e.g., touch input) processes and functions; audio processing instructions  1382  to facilitate audio-related processes and functions; and camera instructions  1384  to facilitate camera-related processes and functions. The instructions described above are merely exemplary and the memory  1370  includes additional and/or other instructions in some embodiments. For instance, the memory for a smartphone may include phone instructions to facilitate phone-related processes and functions. Additionally, the memory may include instructions for an image organizing, editing, and viewing application. The above-identified instructions need not be implemented as separate software programs or modules. Various functions of the mobile computing device can be implemented in hardware and/or in software, including in one or more signal processing and/or application specific integrated circuits. 
     While the components illustrated in  FIG. 13  are shown as separate components, one of ordinary skill in the art will recognize that two or more components may be integrated into one or more integrated circuits. In addition, two or more components may be coupled together by one or more communication buses or signal lines. Also, while many of the functions have been described as being performed by one component, one of ordinary skill in the art will realize that the functions described with respect to  FIG. 13  may be split into two or more integrated circuits. 
     IV. Computer System 
       FIG. 14  conceptually illustrates another example of an electronic system  1400  with which some embodiments of the invention are implemented. The electronic system  1400  may be a computer (e.g., a desktop computer, personal computer, tablet computer, etc.), phone, PDA, or any other sort of electronic or computing device. Such an electronic system includes various types of computer readable media and interfaces for various other types of computer readable media. Electronic system  1400  includes a bus  1405 , processing unit(s)  1410 , a graphics processing unit (GPU)  1415 , a system memory  1420 , a network  1425 , a read-only memory  1430 , a permanent storage device  1435 , input devices  1440 , and output devices  1445 . 
     The bus  1405  collectively represents all system, peripheral, and chipset buses that communicatively connect the numerous internal devices of the electronic system  1400 . For instance, the bus  1405  communicatively connects the processing unit(s)  1410  with the read-only memory  1430 , the GPU  1415 , the system memory  1420 , and the permanent storage device  1435 . 
     From these various memory units, the processing unit(s)  1410  retrieves instructions to execute and data to process in order to execute the processes of the invention. The processing unit(s) may be a single processor or a multi-core processor in different embodiments. Some instructions are passed to and executed by the GPU  1415 . The GPU  1415  can offload various computations or complement the image processing provided by the processing unit(s)  1410 . 
     The read-only-memory (ROM)  1430  stores static data and instructions that are needed by the processing unit(s)  1410  and other modules of the electronic system. The permanent storage device  1435 , on the other hand, is a read-and-write memory device. This device is a non-volatile memory unit that stores instructions and data even when the electronic system  1400  is off. Some embodiments of the invention use a mass-storage device (such as a magnetic or optical disk and its corresponding disk drive) as the permanent storage device  1435 . 
     Other embodiments use a removable storage device (such as a floppy disk, flash memory device, etc., and its corresponding drive) as the permanent storage device. Like the permanent storage device  1435 , the system memory  1420  is a read-and-write memory device. However, unlike storage device  1435 , the system memory  1420  is a volatile read-and-write memory, such a random access memory. The system memory  1420  stores some of the instructions and data that the processor needs at runtime. In some embodiments, the invention&#39;s processes are stored in the system memory  1420 , the permanent storage device  1435 , and/or the read-only memory  1430 . For example, the various memory units include instructions for processing multimedia clips in accordance with some embodiments. From these various memory units, the processing unit(s)  1410  retrieves instructions to execute and data to process in order to execute the processes of some embodiments. 
     The bus  1405  also connects to the input and output devices  1440  and  1445 . The input devices  1440  enable the user to communicate information and select commands to the electronic system. The input devices  1440  include alphanumeric keyboards and pointing devices (also called “cursor control devices”), cameras (e.g., webcams), microphones or similar devices for receiving voice commands, etc. The output devices  1445  display images generated by the electronic system or otherwise output data. The output devices  1445  include printers and display devices, such as cathode ray tubes (CRT) or liquid crystal displays (LCD), as well as speakers or similar audio output devices. Some embodiments include devices such as a touchscreen that function as both input and output devices. 
     Finally, as shown in  FIG. 14 , bus  1405  also couples electronic system  1400  to a network  1425  through a network adapter (not shown). In this manner, the computer can be a part of a network of computers (such as a local area network (“LAN”), a wide area network (“WAN”), or an Intranet, or a network of networks, such as the Internet. Any or all components of electronic system  1400  may be used in conjunction with the invention. 
     Some embodiments include electronic components, such as microprocessors, storage and memory that store computer program instructions in a machine-readable or computer-readable medium (alternatively referred to as computer-readable storage media, machine-readable media, or machine-readable storage media). Some examples of such computer-readable media include RAM, ROM, read-only compact discs (CD-ROM), recordable compact discs (CD-R), rewritable compact discs (CD-RW), read-only digital versatile discs (e.g., DVD-ROM, dual-layer DVD-ROM), a variety of recordable/rewritable DVDs (e.g., DVD-RAM, DVD-RW, DVD+RW, etc.), flash memory (e.g., SD cards, mini-SD cards, micro-SD cards, etc.), magnetic and/or solid state hard drives, read-only and recordable Blu-Ray® discs, ultra density optical discs, any other optical or magnetic media, and floppy disks. The computer-readable media may store a computer program that is executable by at least one processing unit and includes sets of instructions for performing various operations. Examples of computer programs or computer code include machine code, such as is produced by a compiler, and files including higher-level code that are executed by a computer, an electronic component, or a microprocessor using an interpreter. 
     While the above discussion primarily refers to microprocessor or multi-core processors that execute software, some embodiments are performed by one or more integrated circuits, such as application specific integrated circuits (ASICs) or field programmable gate arrays (FPGAs). In some embodiments, such integrated circuits execute instructions that are stored on the circuit itself. In addition, some embodiments execute software stored in programmable logic devices (PLDs), ROM, or RAM devices. 
     As used in this specification and any claims of this application, the terms “computer”, “server”, “processor”, and “memory” all refer to electronic or other technological devices. These terms exclude people or groups of people. For the purposes of the specification, the terms display or displaying means displaying on an electronic device. As used in this specification and any claims of this application, the terms “computer readable medium,” “computer readable media,” and “machine readable medium” are entirely restricted to tangible, physical objects that store information in a form that is readable by a computer. These terms exclude any wireless signals, wired download signals, and any other ephemeral signals. 
     While various processes described herein are shown with operations in a particular order, one of ordinary skill in the art will understand that in some embodiments the orders of operations will be different. For example in the process  500  of  FIG. 5 , the calculation of the water color is shown as taking place before the gamma adjustment of the image, but in other embodiments, the order may be reversed, or the operations may even run in parallel. 
     While various operations are described herein as taking place in specific colorspaces (e.g., RGB colorspace or YIQ colorspace) one of ordinary skill in the art will understand that comparable operations can be performed in other colorspaces in some embodiments. For example, the application of some embodiments perform color adjustments in a YUV colorspace or a YC b C r  colorspace instead of a YIQ colorspace. One of ordinary skill in the art will understand that the invention is not to be limited by the foregoing illustrative details, but rather is to be defined by the appended claims.