Patent Abstract:
Methods and apparatus for graphically representing current data values and possible data values associated with a quantifiable image property. A method includes the steps of displaying to a user a line that represents a range of current data values, displaying to a user a two-dimensional coordinate space in which the two dimensions are respectively parallel to and normal to the line, and representing a range of possible data values by distances along the normal dimension of the coordinate space from corresponding current data values on the line.

Full Description:
CLAIM OF PRIORITY 
   This application claims priority under 35 USC §119(e) to U.S. patent application Ser. No. 60/183,174, filed on Feb. 17, 2000, the entire contents of which are hereby incorporated by reference. 

   BACKGROUND 
   This invention relates to the graphic representation of data values. 
   Digital images used to represent and convey information to a computer user may take a variety of forms such as alphanumeric characters, graphs, and pictures. Digital images may be stored digitally, manipulated, and then rendered on video monitors or printers. 
   Digital images may have a variety of properties such as color, texture, brightness, contrast, and may be associated with nonvisual properties such as speed of motion or sound effects. The properties of an image may be defined when the image is created or modified and may be stored with the image. 
   Image properties are generally quantifiable. For example, the brightness of each pixel or other part of an image may be expressed as a quantity that may vary between 0% white (i.e., 100% black) and 100% white. Quantifiable image properties may be modified through mathematical translations of the data values that define the image properties of the parts of the image. In some systems, the user may alter the data values defining one or more image properties by using a keyboard or other input device. In other systems, a user may modify image properties through a graphical user interface (GUI). For example, a range of possible data values may be displayed graphically to the user and the user may select the desired new data value with a mouse or other pointing device. 
   One particular GUI used to alter image properties uses a control tab of the kind shown in  FIG. 2. A  square  200  representing an x-y coordinate system is displayed to the user. The range of base data values for the image property (image brightness is shown in  FIG. 2 ) is displayed graphically along the bottom horizontal edge (the x-coordinate)  210  of the square, while the range of possible new data values is displayed graphically along the left vertical edge (the y-coordinate)  220  of the square. The diagonal line  230  from the bottom left to the top right corner of the square represents a base state in which each base data value is identical to the new data value (i.e., x=y), indicating that no mathematical transformation has yet been performed. Each point on the line represents all of the pixels (or other parts) of the image that have the brightness value indicated on the x-axis. 
   To alter the image property the user may select a point on the diagonal line (e.g., point A) and drag it to a new position within the square (e.g., point N). Software then generates a new curve  240  that passes through the endpoints of the diagonal line and the new position of the point. The shape of curve  240  depends on choices made by the software designer. The curve  240  defines a mathematical translation of old data values into new data values. Every point along curve  240  has an x-y coordinate, where the horizontal, x-coordinate represents the old data value and the vertical, y-coordinate represents a corresponding new data value. Thus, when the transformation defined by the new curve is applied, every pixel having an old brightness value of x will assume a new brightness value of y. In this way, the brightness characteristics of the whole image can be altered. For example, dark pixels can be made lighter. 
   The GUI shown in  FIG. 2  can be confusing to a user. The diagonal line indicating the base state of no change has a constant slope that users may interpret as implying a constantly increasing change of pixel brightness rather than a lack of change, because rising lines in x-y coordinate systems usually represent constant change. Moving point A to destination N (as indicated by arrow  225 ) to create a new curve may give the impression that the old data value associated with point A (the x-coordinate of point A) has acquired the new data value associated with point N (the y-coordinate of point N). In fact, it is the old data value associated with point B, located directly below point N, that has acquired the new data value associated with point N, because the x-coordinates of points N and B are identical. 
   SUMMARY OF THE INVENTION 
   In general, in a first aspect, the invention features a method of graphically representing base data values and possible data values associated with a quantifiable image property including the steps of displaying to a user a line that represents a range of base data values, displaying to a user a two-dimensional coordinate space in which the two dimensions are respectively parallel to and normal to the line, and representing a range of possible data values by distances along the normal dimension of the coordinate space from corresponding base data values on the line. 
   Implementations of the invention may include the following features. The line may be displayed horizontally and the coordinate space may be skewed from the horizontal direction. The two-dimensional coordinate space may be a polygon, wherein two nonadjacent vertices of the polygon coincide with the ends of the horizontal line in the two-dimensional coordinate space. The polygon may be a parallelogram, wherein the parallelogram includes a first vertical side parallel to a second vertical side and a first skewed side parallel to a second skewed side. The possible data values represented by endpoints of the first vertical side and the second vertical side may include the minimum and maximum of the range of possible data values, wherein the possible data values represented by points on the first skewed side comprise the minimum of the range of possible data values, and wherein the possible data values represented by points on the second skewed side comprise the maximum of the range of possible data values. The data values may be used in a computer graphics display, and the quantifiable image property may include brightness or color. 
   In another aspect, the invention features a method of interactively transforming a graphical representation of data values associated with a quantifiable image property including the steps of displaying to a user a line that represents a range of base data values, displaying to a user a two-dimensional coordinate space in which the two dimensions are respectively parallel to and normal to the line, representing a possible range of data values by distances along the normal dimension of the coordinate space from corresponding base data values on the line, and interactively providing a curve in the coordinate space, a change in each base data value corresponding to the distance along the normal dimension of the coordinate space from the curve to the point on the line representing the base data value. 
   Implementations of the invention may include the following features. Interactively providing a curve in the coordinate space may include selecting a point on the line, dragging the point to a new position in the coordinate space, and defining a curve in the coordinate space through the ends of the line and through the new position of the point. The tangent to the curve at the new position of the point may be parallel to the line. Interactively transforming a graphical representation of data values associated with a quantifiable image property may further include displaying to a user the base data value of the selected point, and displaying to a user the new data value of the point as it is dragged. One or more nodes in the coordinate space may be defined and a curve in the coordinate space through the ends of the line and through the nodes may be defined. The tangent to the curve at each node may be parallel to the line. 
   In a further aspect, the invention features method of graphically representing old data values and new data values, the data values being associated with a quantifiable image property, including displaying to a user a line that represents a range of old data values, displaying to a user a two-dimensional coordinate space in which the two dimensions are respectively parallel to and normal to the line, representing new data values with a curve in the coordinate system, and displaying a line along the normal dimension of the coordinate system between an extremum of the curve and the line. 

   
     DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a block diagram of a computer system suitable for implementing the invention. 
       FIG. 2  is a prior art graphical user interface used for modifying image properties. 
       FIG. 3  is a graphical user interface used for modifying image properties in accordance with the invention. 
       FIG. 4  is a flowchart of a method in accordance with the invention. 
   

   DETAILED DESCRIPTION 
   As shown in  FIG. 3 , a GUI display image  300  includes a square  302  that defines an x-y coordinate system used for modifying the data values associated with quantifiable image properties. The x-coordinate runs along the horizontal direction of square  302  and the y-coordinate runs along the vertical direction of the square, although (unlike a conventional rectilinear coordinate system) a given value of y occupies a vertical position that depends on its location along x-axis. The square  302  contains an inactive background region  310  and an active region  312  in the shape of a parallelogram that is, for example, lighter in color and therefore visually distinguishable from inactive background region  310 . Two sides  303  of the parallelogram active region  312  are parallel to the vertical sides  304  of square  302 , while two sides  305  of parallelogram active region  312  are skewed from the direction of the horizontal sides  306  of the square. A straight, horizontal line  315  in active region  312  runs parallel to the horizontal sides  306  of square  302 , between the two vertices  317  that form the obtuse angles of parallelogram active region  312 . (In this context, the term “line” refers a line segment, a straight segment of finite length.) 
   The straight, horizontal line  315  represents a range of base data values assigned to the image property to be modified (for example, the brightnesses of pixels in an image), and active region  312  represents the parameter space of data values that may be assigned when the base range of data values is modified. The x-coordinate  331  of a point on line  315  corresponds to a base data value within the range of base data values assigned to an image property to be modified. The y-coordinate in active region  312  directly above  333  or below  335  a point on line  315  corresponds to a possible new data value that may be assigned to the point when the image property is modified. 
   Horizontal line  315 , representing base data values for an image property, combined with parallelogram active region  312 , representing possible new data values for an image property, provides an intuitive graphical space for translating base data values into new data values. The ends of horizontal line  315  represent the extrema of a range of base data values. For example, in  FIG. 3 , where brightness is the image property to be modified, the ends of horizontal line  315  correspond to 0% and 100% brightness, and points on line  315  between the ends correspond to intermediate brightness values. Since the points at the ends of horizontal line  315  correspond to the extrema of the range of base data values, upon modification the point at one end of the line  315  may only acquire a larger value and the point at the other end of the line  315  may only acquire a smaller value. Thus, at one end of horizontal line  315  available space in active region  312  exists only above point  318 , because the data value assigned to this point can only increase, while at the other end of line  315  space in active region  312  exists only below point  319 , because the data value assigned to this point can only decrease. Graphically, this requires that parallelogram vertices  317  coincide with the ends of horizontal line  315 . 
   Points on horizontal line  315  between the ends  317  of the line correspond to base data values intermediate between the minimum and maximum of the range of values. Since they are intermediate values, they may be either increased or decreased when modified and, therefore, space exists in active region  312  both above and below line  315  for every point on the line except for the endpoints  317 . For example, in  FIG. 3 , the point  318  at the left end of line  315  represents a data value indicating minimum brightness, so active space only exists above point  318 , while the point  319  of at the right end of line  315  represents a data value that indicating maximum brightness, so active space only exists below point  319 . The point in the middle of line  315  represents 50% brightness and can increase to 100% brightness or decrease to 0% brightness, which is why the active space above it is equal to the active space below it. 
   A graphical bar  320  representing the range of data values currently assigned to the image property runs parallel to the bottom edge  306  of the square  302 . For example, in  FIG. 3 , the image property to be changed is brightness, and graphical bar  320  displays the range of brightness from 0% brightness at the left end of graphical bar  320  to 100% brightness at the right end of graphical bar  320 . 
   In addition to horizontal bar  320  in image  300 , vertical graphical bars  330 , representing the range of possible data values that may be assigned to the image property when it is modified, run parallel to the vertical sides  304  of square  302 . Vertical graphical bars  330  do not run the entire length of the vertical sides  304  of the square. Rather, they run parallel to the vertical sides of parallelogram active region  312 . Graphical bar  331  becomes brighter as it goes up because the brightness of point  318  can only increase, while graphical bar  332  becomes darker as it goes down because the brightness of point  319  can only decrease. 
   A nonorthogonal grid may be drawn inside active region  312 . Vertical grid lines  352  parallel to the sides  304  of square  302  indicate lines of constant base data values. Skewed lines  354 , parallel to the skewed sides of parallelogram active region  312  indicate lines of constant possible data values that the base data values may acquire through a modification of an image property. For example, in  FIG. 3 , line  353  at the bottom of parallelogram active region  312  indicates 0% brightness, line  355  at the top of parallelogram active region  312  indicates 100% brightness and line  354  midway between, and parallel to, lines  353  and  355  indicates 50% brightness. 
   A user may modify the data values associated with a quantifiable image property by altering the horizontal line  315 . A user may select a starting point, e.g., point A, on horizontal line  315  with a mouse or other pointing device and drag the point to a new location in active region  312 , e.g., point N. When the user stops dragging the starting point and releases it in active region  312 , a new line  360  (which in general may be a curved segment of essentially any shape) is created and drawn though the ends  317  of line  315  and the new position, point N, of the point the user has dragged. In one implementation, the tangent to new line  360  at point N is parallel to horizontal line  315 . New line  360  defines the modification of the data values associated with the quantifiable image property, in that the x-coordinate of a point on new line  360  corresponds to the old data value and the y-coordinate of the point on new line  360  corresponds to the new data value. Thus, for example, dragging starting point A on line  315  in  FIG. 3  to point N on new line  360  causes grays of 25% brightness in the original image to acquire a value of approximately 66% brightness. 
   Further referring to  FIG. 3 , when a user drags a point on line  315  to a new location, e.g., point N, a vertical line  370  perpendicular to line  315 , from point N to line  315  can be displayed to the user. Vertical line  370  serves to remind the user that it is the x-coordinate of point N, rather than the x-coordinate of starting point A, that corresponds to the old data value when the image property is modified. A dot  372  at the base of vertical line  370  on line  315  can be displayed to further reinforce this notion. 
   New line  360 , passing through end points  317  of line  315  and point N, may be displayed to the user while the starting point is being dragged and before the starting point is released by the user. New line  360  will necessarily change as the starting point is dragged to different locations within active region  312  until the point is released. Additionally, the value of the old data value and the new data value it will acquire when the starting point is released may be displayed either through graphical aids  380  or through a numerical display  382 . For example, in  FIG. 3 , both graphical aids  380  and numerical display  382  indicate that moving starting point A to point N results in changing grays of 25% brightness to grays of 66% brightness. 
   As shown in  FIG. 4 , data values corresponding to an image property may be modified with the use of an x-y coordinate system that includes a skewed active region and a horizontal line through the active region  400 . The coordinate system, the active region and the horizontal line are displayed to a user  400 . The user selects a point on the horizontal line  410 , through the use of a mouse or other pointing device, which may include keyboard commands. The user then drags the selected point to a new location within the active region  420 . While the selected point is dragged, a vertical line may be drawn from the point to the horizontal line. The user releases the selected point  430  at the desired destination point and a new line, passing through the ends of the horizontal line and through the destination point, is defined  440 . Data values corresponding to the image property are redefined according to the shape of the new line  450 . 
   Other embodiments are within the scope of the following claims. 
   For example, when an image property is modified by modifying the horizontal line and creating a new line, the new line need not be defined by only the endpoints of the horizontal line and a single point dragged by the user. More than one point on the horizontal line may be dragged to new positions and the new line may be defined to pass through all of the new positions of the points in addition to the endpoints of the horizontal line. The new line may also be defined by use of control points that the new line does not pass through. Furthermore, positions of points through which new line  360  passes need not be defined by dragging points from line  315 , but may be defined by other selection methods, such as with a mouse or other such pointing device or by entering the new point&#39;s coordinates with, e.g., a keypad. The multiple new positions of points selected by the user may define the nodes of the new line that passes through them and define the shape of the new line. 
   The horizontal line that represents the range of base values need not be strictly horizontal. It can, for example, be vertical or at some angle to vertical or horizontal that is close enough to vertical or horizontal to provide the same benefits. In other arrangements, the line can be at any angle to horizontal or vertical if the skewed region showing the possible new values has a grid that is generally perpendicular to the line. The shape of the active region of possible new data values need not be a parallelogram. 
   The line  370  that shows the change in y-value for a base x-value is useful even with the known arrangement of FIG.  2 . 
   A variety of mathematical or empirical functions may be used for drawing curve  360  to pass through the point N and the end points of line  315 . 
   The relationship of (i) the normal distance of a point on new line  360  to line  315  to (ii) the change from old value to new value need not be linear. Thus, for example, the scale of the grid in the active region can be logarithmic in the normal direction. 
   The base values can be default values with the new line showing a current transformation from the default. The base values can also be values the resulted from a previously-performed transformation. Or, the base values can be selected in some other way. 
   The techniques described here may be implemented in hardware, software, or a combination of the two. The techniques may be implemented in computer programs executing on programmable computers that each include a processor, a storage medium readable by the processor, including volatile and nonvolatile memory and/or storage elements, and other suitable input and output devices. 
     FIG. 1  illustrates one such computer system  100 , including a central processing unit (CPU)  110 , random access memory (RAM)  120 , read only memory (ROM)  122  and an input/output controller  130  coupled by a CPU bus  140 . The input/output controller  130  may also be coupled by an input/output bus  198  to input devices such as a keyboard  160 , a pointing device  170 , e.g., a mouse, and output devices such as a display device  180 , e.g., a video monitor. A computer program implementing a routine that manages the control box shown in  FIG. 3  may be stored in RAM  120 , ROM  122 , or on a storage medium or device  190 , e.g., CD-ROM, hard disk or magnetic diskette. The computer program may be readable by a general or special purpose programmable computer for configuring and operating the computer to perform the techniques described here.

Technology Classification (CPC): 6