Patent Abstract:
One embodiment of the present invention provides a system for viewing objects on a display that allows a user to scroll through the objects by varying a non-positional display attribute of the objects. This non-positional display attribute may include attributes such as transparency, fadedness and size. The system operates by receiving an intrinsic value for an object, which specifies a value for a display attribute associated with the object. The system also receives a reference value for the display attribute against which intrinsic values for objects are compared. This reference value may be received from a user through a scroll bar that is manipulated by the user. The system uses the intrinsic value and the reference value to compute a display value for the object. Next, the object is displayed using the display value to specify the non-positional display attribute for the object. Thus, in one embodiment of the present invention, objects that have an intrinsic value equal to reference value are displayed normally (opaquely) without any fading. Other objects that have a display value close the reference value are displayed translucently, giving the impression that objects are “emerging from the fog” or gradually “fading away.” Objects with a large difference between the intrinsic value of the object and the reference value are not displayed at all.

Full Description:
BACKGROUND 
     1. Field of the Invention 
     The present invention relates to user interfaces for computer systems. More particularly, the present invention relates to a method and apparatus for viewing a collection of objects on a display that allows a user to “scroll” through the objects by varying non-positional display attributes for objects, such transparency, color or size, instead of varying spatial location. 
     2. Related Art 
     One of the scarcest resources in today&#39;s computing devices is screen space. Even though the processing power and storage capacity of computing devices has increased by several orders of magnitude during the past twenty years, the average computer screen size has barely doubled. Although the resolution, clarity, and the overall quality of the displays has improved substantially, the actual size of the work area remains relatively limited. Screen space limitations are particularly apparent in the emerging pocket-sized computing devices and personal organizers. These pocket-sized computing devices often have display sizes that are less than a few hundred or a few thousand square pixels. 
     Spatial scrolling is a conventional and useful way to deal with limited screen real estate. When a user runs out of screen space, the user can scroll the display so that old objects move off the screen and new screen space becomes available. Conventional “spatial scrolling” suffers from a number of problems that undermine the benefits of the windows-icons-desktop-folders metaphor presently used in most user interfaces. 
     One problem is that spatial scrolling undermines spatial memory. User interfaces based upon the windows-icons-desktop-folders metaphor have proven quite powerful because they allow a user to organize data by placing icons at various “locations” on a computer display. Human users tend to have good “spatial memory,” which allows them to remember that particular items are located at specific locations on a display. Spatial scrolling undermines spatial memory because objects move as they scroll across a display. 
     Another problem with spatial scrolling is “discontinuous salience.” “Salience” is a measure of the prominence of an object in a display, in other words how much the object stands out from the rest of the display. As objects grow larger or become brighter they become more salient. However, when an object moves off the screen, its salience drops to zero. For example, in the case of three-dimensional scrolling, an object becomes increasingly salient as the object moves closer to the reference point of the display. However, salience drops to zero as the object passes through the forward clipping plane of the display. Furthermore, two objects that are close together in three-dimensional space appear to diverge and move apart across the screen as the reference point of the display moves closer to the objects. 
     What is needed is a method for scrolling through objects in a graphical display that preserves spatial memory and continuity of salience. 
     SUMMARY 
     One embodiment of the present invention provides a system for viewing objects on a display that allows a user to scroll through the objects by varying a non-positional display attribute of the objects. This non-positional display attribute may include attributes such as transparency, fadedness and size. The system operates by receiving an intrinsic value for an object, which specifies a value for a display attribute associated with the object. The system also receives a reference value for the display attribute against which intrinsic values for objects are compared. This reference value may be received from a user, for example through a scroll bar that is manipulated by the user. The system uses the intrinsic value and the reference value to compute a display value for the object. Next, the object is displayed using the display value to specify the non-positional display attribute for the object. 
     In one embodiment of the present invention, computing the display value for the object includes computing a difference between the intrinsic value for the object and the reference value. In a further variation, the function used to compute the display value is continuous and assumes a higher value when the absolute value of the difference approaches zero, and a lower value when the absolute value of the difference becomes large. 
     In one embodiment of the present invention, display values are computed for the objects before any objects are displayed. Next, the objects are sorted by display value and displayed in sorted order. This ensures that objects with smaller display values are not displayed on top of objects with larger display values. 
     In one embodiment of the present invention, objects that have the same value for a display attribute belong to the same “layer” and are hence displayed at the same time. Objects that have an intrinsic value equal to reference value are displayed normally (opaquely) without any fading. Other objects that have a display value close the reference value are displayed translucently, giving the impression that objects are “emerging from the fog” or gradually “fading away.” Objects with a large difference between the intrinsic value of the object and the reference value are not displayed at all. This entire process is fully reversible and repeatable. Hence, a user can move the reference value higher and lower, viewing objects with different intrinsic values at varying levels of fading. 
     In one embodiment of the present invention, visualization of objects is implemented cumulatively. This means when the user moves the reference value higher, the display behaves as described above. However, when the user moves the reference value lower, the display shows cumulatively more and more objects until all possible objects become visible. 
    
    
     BRIEF DESCRIPTION OF THE FIGURES 
     FIG. 1 illustrates a computing device in accordance with an embodiment of the present invention. 
     FIG. 2 illustrates one form of stationary scrolling in accordance with an embodiment of the present invention. 
     FIG. 3 illustrates another form of stationary scrolling in accordance with an embodiment of the present invention. 
     FIG. 4 illustrates how computer system components connect with the visualization subsystem in accordance with an embodiment of the present invention. 
     FIG. 5 illustrates the structure of the visualization subsystem in accordance with an embodiment of the present invention. 
     FIG. 6 is a flow chart illustrating the process of displaying objects in accordance with an embodiment of the present invention. 
     FIG. 7 is a flow chart illustrating how objects are sorted by display value to establish a display order in accordance with an embodiment of the present invention. 
    
    
     DETAILED DESCRIPTION 
     The following description is presented to enable any person skilled in the art to make and use the invention, and is provided in the context of a particular application and its requirements. Various modifications to the disclosed embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be applied to other embodiments and applications without departing from the spirit and scope of the present invention. Thus, the present invention is not intended to be limited to the embodiments shown, but is to be accorded the widest scope consistent with the principles and features disclosed herein. 
     The data structures and code described in this detailed description are typically stored on a computer readable storage medium, which may be any device or medium that can store code and/or data for use by a computer system. This includes, but is not limited to, magnetic and optical storage devices such as disk drives, magnetic tape, CDs (compact discs) and DVDs (digital video discs), and computer instruction signals embodied in a carrier wave. For example, the carrier wave may carry information across a communications network, such as the Internet. 
     Computer System 
     FIG. 1 illustrates computing device  102  in accordance with an embodiment of the present invention. Computing device  102  may include any type of computing device with a display, including a personal computer, a workstation or a mainframe computer system. Computing device  102  may additionally include portable computing devices, such as a personal organizer, a two-way pager, a cellular telephone or a mobile web browser. 
     Computing device  102  includes a display  104  for outputting data to a user. Computing device  102  also includes a number of input devices, including keyboard  106  and mouse  108 , for receiving input from the user. Note that many other types of input devices can be used with the present invention, including input buttons on a personal organizer or a touch sensitive display. Display  104  may include any type of display device on a computer system, including but not limited to, a cathode ray tube, a flat panel display, a LCD display or an active matrix display. 
     Computing device  102  also includes software architecture  120 . At the lowest level, software architecture  120  includes operating system  128 , which supports the execution of applications on computing device  102 . In one embodiment of the present invention, operating system  128  includes the WINDOWS operating system distributed by the Microsoft Corporation of Redmond, Wash. In another embodiment, operating system  128  includes the Palm OS that is contained within the Palm connected organizer, distributed by the 3COM corporation of Sunnyvale, Calif. 
     Alongside operating system  128  is graphics routines  124 . Graphics routines  124  include any routines for facilitating the generation of images on display  104 . 
     User interface  122  resides on top of operating system  128  and graphics routines  124 . User interface  122  interacts with operating system  128  and graphics routines  124  to provide an output to display  104  in accordance with an embodiment of the present invention. 
     Finally, applications  121  reside on top of user interface  122 . Applications  121  may include any type of applications running on computing device  102  that can be used in conjunction with user interface  122 . 
     Computing device  102  also includes hardware architecture  130 . Hardware architecture  130  includes processor  132 , memory  134 , display  104 , secondary storage device  136 , input devices  138  and communication interface  137 . These components are coupled together by bus  133 . Processor  132  may include any type of computational engine for executing programs within computing device  102 . This includes, but is not limited to, a microprocessor, a device controller, and a computational device within an appliance. Memory  134  may include any type of random access memory for storing code and data for use by processor  132 . Secondary storage device  136  may include any type of non-volatile storage device for storing code and data to for use by processor  132 . This includes, but is not limited to, magnetic storage devices, such as a disk drive, and electronic storage devices, such as flash memory or battery backed up RAM. Display  104  (described above) may include any type of device for displaying images on a computer system. Input devices  138  may include any type of devices for inputting data into computing device  102 . This includes keyboard  106  and mouse  108  as well as input buttons or a touch-sensitive display. Communication interface  137  may include any type of mechanism for communicating between computing device  102  and an external host. This may include a linkage to a computer network through electrical, infrared or radio signal communication pathways. 
     Stationary Scrolling 
     FIG. 2 illustrates one form of stationary scrolling in accordance with an embodiment of the present invention. In this embodiment, a number of objects  204 ,  206 ,  208  and  210  appear on display  104 . Each of these objects has an “intrinsic value” for a particular display attribute. This intrinsic value is combined with a reference value for the attribute to produce a display parameter for the object. FIG. 2 presents three representations of display  104 , a top display, a middle display and a bottom display, which depict display  104  at different points in time as slider  202  moves in a downward direction. 
     In the top display  104 , objects  204 ,  208  and  210  are drawn with dashed lines. This indicates that objects  204 ,  208  and  210  have less salience than object  206 , which is drawn with solid lines. Because objects  204 ,  208  and  210  have less salience, they appear more faded (or more transparent) than object  206 . 
     Note that fading of an object can be implemented in different ways. Color or grayscale levels can be varied when drawing the object. Pixels of the object can be selectively changed to either blank or transparent while the object is being drawn. Alternatively, a predefined set of icons with varying levels of fadedness can be pre-defined for each type of display object. 
     Note that a user can change a scrolling reference value for the display by moving slider  202  up or down using a pointing device such as mouse  108 . 
     In middle display  104 , slider  202  has been moved in a downward direction so that the scrolling reference value is closer to intrinsic values for objects  208  and  210 . Hence, objects  208  and  210  have greater salience and are drawn with solid lines. At the same time, the scrolling reference value is farther from the intrinsic value for object  206 . Hence, object  206  has less salience so it is drawn with dashed lines. The scrolling reference value has also moved closer to the intrinsic value for object  204 . Hence object  204  has more salience, but not as much as objects  208  and  210 , so object  204  is still drawn with dashed lines. 
     In bottom display  104 , slider  202  has been moved even further downward so that the scrolling reference value is closer to the intrinsic value for object  204 . Hence, object  204  has greater salience and is drawn with solid lines. Objects  206 ,  208  and  210  have less salience, and are drawn with dashed lines. 
     Note that the spatial locations of objects  204 ,  206 ,  208  and  210  are preserved because objects  204 , 206   208  and  210  do not move. However, objects  204 ,  206 ,  208  and  210  may become less visible or even invisible as they fade or become more transparent. 
     Also note that discontinuity of salience is no longer a problem. An object becomes increasingly more salient as the scrolling reference value controlled by slider  202  comes closer to the intrinsic value of the object. A point of maximum salience is reached when the intrinsic value matches the scrolling reference value. When the scrolling reference value moves past the intrinsic value, salience gradually tails off and the object gradually fades or becomes more transparent. In one embodiment of the present invention, if the salience of an object falls below a threshold value, the object is no longer visible. 
     In one embodiment of the present invention, an object can be selected to remain at a fixed salience value (typically the maximum salience value) as the scrolling reference value changes. Hence, the display for this “fixed” object will not change as other objects in the display fade or become more transparent. 
     FIG. 3 illustrates another form of stationary scrolling in accordance with another embodiment of the present invention. In the embodiment illustrated in FIG. 3, salience is represented by relative sizes of objects. As the salience of an object increases, the object grows larger. Conversely, as the salience of an object decreases the object becomes smaller. 
     For example, in FIG. 3, in top display  104 , object  304  has a large salience, and is hence represented by a large square. In middle display  104  and bottom display  104 , as slider  202  moves downward the salience of object  304  diminishes because the scrolling reference value controlled by slider  202  moves away from the intrinsic value of object  304 . Hence, the size of object  304  decreases. 
     For object  302  the reverse is true. In top display  104 , object  302  has a low salience value and is represented by a small circle. In middle display  104  and bottom display  104 , as slider  202  moves downward, the salience of object  302  increases. Hence, the size of object  302  increases. 
     Objects  306  and  308  behave differently. They have the highest salience in middle display  104  and are hence represented by large triangles. In the top display  104  and the bottom display  104 , the salience of objects  306  and  308  decreases, hence the size of objects  306  and  308  decreases. 
     Scrolling of both the stationary variety and the non-stationary variety can be described more formally as follows. Consider a set of displayable objects, 0={O i }with each element O i  located in an abstract N-dimensional space, S. The location of each object O i  in this space is an N-dimensional vector, x. We call vector x the display location in S. The numbers in x determine how an object appears on the screen, and therefore affect the salience of the object as perceived by the user. 
     The components of x may represent visual characteristics such as horizontal and vertical position on the screen, transparency, fadedness, and size. Note these visual characteristics affect the objects salience, but not its identity: moving an object through this space S will not substantially affect the user&#39;s perception of what the object is, merely how it looks. For example, simply changing the position of a document icon does not change the user&#39;s ability to identify it, whereas scrambling the colors, replacing the shape, and embedding an arbitrary bitmap in its surface may make identification difficult. 
     The components of x may also represent other display attributes, such as shape, saturation of color, hue, the speed with which the object blinks or wiggles, the degree to which the object is in focus or blurred, the thickness of the object&#39;s outline, and so forth. 
     To define scrolling, we associate with the user with a scrolling reference parameter p in S. In conventional text scrolling for example, p is a single number representing the vertical offset of the user&#39;s current view into the document: the value of p is determined by the position of the scroll bar. In one possible definition for scrolling, set  0  is scrollable if each object O i  also has an intrinsic location x I , in S which is related to the display location x through the scrolling reference parameter, p,and a scrolling function,f. In other words, x=f(x I −p). 
     Both f and p are in general vectors so they may affect more than one aspect of the display location. Furthermore, in order to be useful in a conventional way, f(x) usually takes on values associated with greatest salience at or near x=0. 
     An infinite number of different functions may be used for f. These functional preferably have the greatest value (or salience) when the absolute value of x I −p is small, and a smaller value when the absolute value of xI−p is large. In this way, an object&#39;s salience will be greatest when the user&#39;s scrolling reference value is closest to the intrinsic value of the object. Also, these functions are preferably smoothly varying to preserve continuity of salience. For example, the function can be f(x)=Aexp(−x 2 /r 2 ) or f(x)=c 2 /(c 2 +x 2 ). Both of these are smoothly varying functions that reach a peak when x=0. 
     Visualization Subsystem 
     FIG. 4 illustrates how components in computing device  102  connect with visualization subsystem  404  in accordance with an embodiment of the present invention. Visualization subsystem  404  handles drawing and outputting of objects to display  104 . As part of these duties, visualization subsystem  404  implements stationary scrolling. 
     Visualization subsystem  404  is coupled to application specific logic and data  406 , which contains code and data to implement the underlying non-visual functions of an application. For example, application specific logic and data  406  can compute a bank account balance, while visualization subsystem  404  can display the bank account balance. 
     Both visualization subsystem  404  and application-specific code and logic  406  receive input from input/event dispatcher  402 , which itself receives input from a user operating input devices  138 . Input devices  138  may include, for example, keyboard  116  and mouse  108  from FIG.  1 . Finally, visualization subsystem  404  outputs images of the objects to display  104 . 
     FIG. 5 illustrates the internal structure of visualization subsystem  404  in accordance with an embodiment of the present invention. Visualization subsystem  404  includes window displayer  502 , which controls the displaying of objects in display  104 . 
     Window displayer  502  communicates with scrollable view  504  and user input module  524 . Scrollable view  504  controls the scrolling of a collection of display objects. In the embodiment illustrated in FIG. 3, scrollable view  504  controls display objects  506 ,  512  and  518 . Each display object contains a number of display attributes containing numbers. These display attributes may specify color, size and positional attributes for the object. More specifically, display object  506  includes display attributes  508 , display object  512  includes display attributes  514 , and display object  518  includes display attributes  520 . 
     Display objects  506 ,  508  and  510  are also associated with other non-display related data, such as bank account balances, contained in application-specific data and logic  406 . More specifically, display object  506  is associated with other data  510 , display object  512  is associated with other data  516 , and display object  518  is associated with other data  522 . 
     In order to compute the above-described functions, window displayer  502  accesses scrolling reference value  526  through user input module  524 . A user may enter a scrolling reference value  526  by moving slider  202  (from FIG. 2) using mouse  108  (from FIG.  1 ). This causes input/event dispatcher  402  to send scrolling reference value  526  through window displayer  502  into user input module  524 . User input module  524  finally stores scrolling reference value  526 . 
     Window displayer  502  also includes methods to calculate display values for display objects  506 ,  512  and  518  based on scrolling reference value  526 . 
     Process of Displaying Objects 
     FIG. 6 is a flow chart illustrating the process of displaying objects in accordance with an embodiment of the present invention. The system starts by drawing a background against which the objects are to be displayed (step  601 ). Drawing this background may include blanking out or overwriting an existing display. For each object to be displayed, the system gets an intrinsic value for the object, which is a value for a non-positional display attribute (step  602 ). The system also receives a scrolling reference value  526  (step  604 ). This scrolling reference value  526  may be received from a user through a user interface, such as slider  202  in FIG.  1 . Alternatively, scrolling reference value  526  may be taken from another source, such as a system clock. Next, the system uses a function to compute a display value for the object based upon the intrinsic value for the object and the scrolling reference value  526 . Recall that this display value may be calculated as a function of the difference between the object&#39;s intrinsic value and the scrolling reference value  526 . Finally, the object is displayed using the calculated display value to specify the non-positional display attribute (step  608 ). 
     FIG. 7 is a flow chart illustrating how objects are sorted by display value to establish a display order in accordance with an embodiment of the present invention. It is desirable for objects with greater salience to be displayed more prominently than objects with less salience. Hence, it is desirable for objects with greater salience to be drawn later than objects with less salience, so that objects with less salience do not cover or obscure objects with greater salience. To this end, it is desirable to draw objects in increasing order of salience. The system accomplishes this by first computing display values for all objects in the display (step  702 ). After the display values have been computed, the system sorts the objects in ascending order of display value (step  704 ). Finally, the system draws the objects on the display in increasing order of display value from lowest display value to highest display value. 
     The foregoing descriptions of embodiments of the invention have been presented for purposes of illustration and description only. They are not intended to be exhaustive or to limit the invention to the forms disclosed. Accordingly, many modifications and variations will be apparent to practitioners skilled in the art. Additionally, the above disclosure is not intended to limit the invention. The scope of the invention is defined by the appended claims.

Technology Classification (CPC): 8