Patent Document

TECHNICAL FIELD 
     The invention relates generally to computer browsing through images and more particularly to providing a low impact means for viewing the display information of memory-stored items such as digital image files or computer desktop windows. 
     BACKGROUND ART 
     Digital cameras have a memory capacity that allows storage of a much larger number of images than conventional film-based cameras. As another advantage, some digital cameras permit a folder system to be created for organizing internally stored digital images. For example, one folder may be designated as “Vacation” and another folder may be designated as “Family Gathering.” Images can then be organized in a manner determined by the user. However, if a folder contains a large array of images, searching for a particular image may become tedious. 
     The difficulty in identifying a particular image is compounded when the image files stored on the digital camera are downloaded to a computer system having image files that were previously downloaded from the same or a different digital camera or from another source of image files (e.g., the global communications network referred to as the Internet). With each such download of image files, there is a decreasing likelihood that a user will be able to remember the storage locations of individual images, even if the user carefully labels folders and the images. For example, there may be ten pictures of sunsets that are difficult to distinguish without opening the image files. Thus, a user may open all ten image files before the desired picture is identified. Without careful organization and labeling, the user may be required to open far more files in order to identify a particular picture. 
       FIG. 1  is an illustration of a graphical user interface (GUI)  10  that reduces the difficulty in browsing through stored images. Rather than opening each image using an application program that enables complex manipulations, such as image cropping or zoom, the images may be displayed in a dedicated viewing window  12  that is adjacent to the menu window  14  in which folders and files are listed. In  FIG. 1 , a folder  16  has been opened to reveal that there are five available image files. As is well known in the art, a display icon (or cursor)  18  can be used in the opening and closing of folders. A computer mouse controls the movement of the display icon along the graphical user interface, which is presented on a display, such as the screen of a computer monitor. The display icon may also be manipulated using a trackball or similar device. In the use of a computer mouse, the display icon  18  is positioned over the folder  16  and “clicked” in order to open the folder. After the folder is opened, the icon can be relocated to one of the image files in order to present the stored image within the viewing window  12 . Thus, by positioning the icon to “contact” the file name “PERSON,” and clicking, the image  20  of a person positioned in a chair appears within the viewing window. If the image is the desired image, the file may be opened within the more sophisticated application program. 
     While the browsing approach described with reference to  FIG. 1  provides an improvement over a requirement of initially opening each image file within the sophisticated application program, the process is still often tedious to the user. Moreover, the repetitive mechanics of moving the display icon  18  and clicking the computer mouse may eventually result in injury to the user. 
     A method for reducing the difficulty in finding a particular file (such as an image file) is described in U.S. Pat. No. 6,067,086 to Walsh. Files are divided into different categories by a user. Each category is then associated by the user with one or more graphical image, with the selection of the image being based upon providing a mnemonic device for identifying the category and for differentiating the category from other categories. For example, an image of a skier may be used to designate a “sports” image set, while an airplane image may be used to designate a “transportation” image set. The GUI arrangement of Walsh enables the computer system to display the graphical images of one or more image sets, as selected by the user, as well as to display identifications of the files associated with the displayed graphical images. For example, the file identifications may be presented in a pop-up menu, so that the user may select and activate a file by clicking on its identification in the pop-up menu. When the user activates a file, the computer system loads the appropriate application program and opens the file. While the Walsh method provides an improvement over the use of generic folder appearances, the method relies upon the organizational skills and the memory of a user. Particularly in those situations in which more than one user has access to a computer system, this reliance upon organizational skills and memory may lead to unsatisfactory results. Moreover, the viewing of multiple image files still requires the repetitive point-and-click approach. 
     What is needed is a method and system that reduce the tediousness of browsing through the display information of memory-stored items, such as either image files from a photograph library or opened computer desktop windows. 
     SUMMARY OF THE INVENTION 
     In accordance with the invention, the contents of files in a set of stored files are displayed as a direct result of tracking the movement of a display icon across a stack of partially overlapping images. Each image is representative of the display information (i.e., contents) of a particular file stored in non-volatile memory or a desktop window stored in volatile memory. In one embodiment, the files are digital image files. 
     As a first step, the stack of images is presented on a display, such as a computer monitor. The position of the display icon is controlled by a user-manipulable device, such as a computer mouse or trackball. Thus, the display icon is a cursor. Typically, the images in the stack that are perceived as being rearward images are partially covered by the images that are perceived as being forward. As a result, only the foremost image is shown in its entirety when the cursor resides in a position away from the stack. However, as the cursor is moved into perceived contact with one of the images, that image is shown in its entirety. The images in the stack may be referred to as first-level (stack level) images, with the cursor-selected image being displayed as a second-level (transitory) image. In the preferred embodiment, the second-level image is offset from the symmetry of the stack. For example, if the stack is an arrangement in which the first-level images are diagonally positioned, the second-level image is axially misaligned, but adjacent to the stack. This allows a user to browse through the images in the stack without a significant shift in eye positioning. As stated, the generations of the second-level images are directly responsive to the movement of the cursor, rather than to a combination of cursor positioning and another user-initiated designation, such as mouse clicking. By scanning the cursor across the stack in a path in which the cursor is moved into sequential alignment with the images, the second-level images are generated in a corresponding sequence. 
     While not critical, the method may also include forming third-level images in a window that is separate from the window in which the stack is displayed. A third-level image is generated in response to a user selection of one of the images in the stack. Thus, the second-level images are formed as a direct response of cursor positioning, while the third-level images may be formed as a combined response of cursor positioning and mouse clicking. The third-level image has more permanency and may be used for the purpose of file manipulation (e.g., file transfer) or image manipulation (e.g., image cropping). 
     The number of images within the stack may be fixed or may be determined by the user. If the images in the stack are a subset of the total stored images, the method preferably includes a mechanism for enabling automated stack substitutions. As one embodiment, an incrementing icon is positioned on a first side of the displayed stack and a decrementing icon is positioned on an opposite side. Merely by positioning the cursor in alignment with the incrementing icon, a second-level image is formed for each of the images in the stack, a next stack is displayed, and the process continues until the end of the collection of files is reached. A reverse pattern is followed when the cursor is positioned in alignment with the decrementing icon. 
     As previously stated, in one embodiment the files are image files. For example, the image files may be photographs generated by a digital camera. The invention may be practiced at the camera or at a computer to which the images are downloaded. Other embodiments are contemplated. As examples, the first-level images and second-level images may be thumbnails from different digital video clips or may be replicas of opened desktop windows. In the video clip embodiment, by selecting a thumbnail, the third-level image is presented as the clip in a play condition. 
     In addition to the display information, the file information may be presented when the cursor is moved in alignment with an image. The file information may include the file name, the stored location, and the file size. Where the method is implemented from a web page of the World Wide Web, the file information preferably includes the Universal Resource Locator (URL) of the web page from which the image is generated. The selection of a second-level image then launches the web page. As another possible application, the images in the stack may be display information of text files that are browsed. 
     An advantage of the invention is that the stack provides the images in an overlapping relationship, so that screen real estate is preserved. That is, the stack provides a compact arrangement for document browsing. Another advantage is that the browsing approach significantly reduces the tediousness of image searching. Mouse clicking is needed only when a “hit” or potential hit has been reached. Preferably, the image browsing approach allows file manipulation with regard to storage, transmission and the like. That is, without the cursor leaving the window in which the stack is displayed, the method preferably allows files to be selected for manipulation operations such as changes in folder storage. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is an illustration of a graphical user interface in accordance with the prior art. 
         FIG. 2  is a schematic illustration of file browsing steps that are followed in accordance with the present invention. 
         FIG. 3  is an illustration of one window of a graphical user interface for cursor-position browsing in accordance with the invention of FIG.  2 . 
         FIG. 4  is an illustration of various windows within a graphical user interface employing the techniques of FIG.  3 . 
         FIG. 5  is a process flow of steps that may be followed in accordance with the invention. 
         FIG. 6  is a simplified block diagram of components for implementing the invention. 
         FIG. 7  is an illustration of a number of open desktop windows on a computer monitor, in accordance with the prior art approach. 
         FIG. 8  is an illustration of the computer monitor of  FIG. 7 , but with a window browsing stack in accordance with the present invention. 
     
    
    
     DETAILED DESCRIPTION 
     With reference to  FIG. 2 , an “active cardstack”  22  is shown as having five images  24 ,  26 ,  28 ,  30  and  32 . The images extend diagonally and provide a perception of rearward images being partially covered by forward images, so that only the foremost image  24  is shown in its entirety. Each of the images represents display information of a memory-stored item, such as image files in non-volatile memory or opened desktop windows from volatile memory (random access memory). The invention will be described primarily in the embodiment in which the memory-stored items are image files, such as digital photographs. However, other applications of the invention will be described below. 
     Since the active cardstack  22  is arranged such that each image  24 - 32  is at least partially exposed, a display icon, such as a cursor, may be moved into perceived contact with any one of the images. The images may be described as first-level images. However, when the cursor is brought into contact with one of the images, a second-level image is formed. Thus, the cardstack is a dynamic stack that is manipulated merely by movement of the cursor onto the stack. It is not necessary to “click” the device that manipulates the cursor (e.g., a mouse) or to register a keyboard keystroke. In the center portion of  FIG. 2 , a cursor  34  is shown as being positioned over the second image  26 . This causes a second-level image to be generated in a position offset from the original position. In the embodiment that will be described with reference to  FIGS. 3 and 4 , the first-level image is preserved and the second-level image is shown in its entirety. Regardless of whether the approach of  FIG. 2  or the approach of  FIGS. 3 and 4  is utilized, the mere repositioning of the cursor causes the stack to be modified to an “activated cardstack”  36 . 
     If the cursor  34  is scanned across the images  24 - 32  along a path in which the cursor is sequentially aligned with the images, a corresponding sequence of second-level images will be presented to a viewer. In this manner, each of the images  24 - 32  can be reviewed for content without requiring a repetitive point-and-click process. 
     The number of images within the original cardstack  22  may be fixed or may be selected by the user. If the number of images  24 - 32  is less than the total number of images that can be browsed, the preferred embodiment allows continued browsing without requiring a user input beyond the positioning of the cursor  34 . For example, if the cursor  34  is located immediately to the right of the cardstack  36 , as viewed in  FIG. 2 , the next subset of images  38 ,  40 ,  42 ,  44  and  46  is introduced as a second active cardstack  48 . For the purpose of reducing the likelihood that a new cardstack will be introduced unintentionally, there should be a threshold time for the positioning of the cursor before the cardstack is changed. Moreover, stack-to-stack incrementing and decrementing icons may be formed to the right and left of the cardstack, respectively, as will be described with reference to FIG.  3 . By positioning the cursor  34  over the decrementing icon, the cardstack  48  may be resubstituted with the original cardstack  22 . 
     Referring now to  FIG. 3 , a stack  50  of first-level images  52 ,  54 ,  56 ,  58  and  60  is shown in greater detail. A cursor  62  is in perceived contact with the center image  56 , causing a second-level image  64  to be generated. Unlike  FIG. 2 , the second-level image  64  is shown in its entirety. This is the preferred embodiment, but is not critical. As can be seen, a sufficient portion of each first-level image  52 - 60  is exposed to allow a user to utilize the exposed portions as mnemonic devices. As the number of images in the stack is increased, the ratio of the exposed portion to the overlapped portion will decrease, but the value of the mnemonic aid may be increased, since there will be more images to consider. 
     The window  66  in which the stack  50  resides includes a stack-to-stack incrementing icon  68  and a stack-to-stack decrementing icon  70 . By positioning the cursor  62  in alignment with the incrementing icon  68  for a set period of time, a second stack will be presented to the user. For example, if there are  75  digital images within a library, the entire library will be displayed in stacks of five images if the cursor is left in position along the incrementing icon  68 . In the preferred embodiment, each image in a stack is displayed as a second-level image before the stack is changed. Thus, the process will scan through all  75  images in the library. The decrementing icon  70  operates in the reverse manner. Optionally, the controlling computer program is configured to allow instant incrementing or decrementing by clicking the computer mouse when the cursor  62  resides on the appropriate icon  68  or  70 . 
     In addition to the display of the second-level image  64 , positioning the cursor  62  in perceived contact with the exposed region of the first-level image  56  triggers the display of file information  72  regarding the image. The file information shown in  FIG. 3  identifies the storage location and the size of the image. Other information may be included. For applications in which the images  52 - 60  represent web pages, the file information may be the URLs of the images. 
     Referring now to  FIG. 4 , the window  66  of  FIG. 3  is shown as being a component of a graphical user interface  74  that includes three other windows  76 ,  78  and  80 . The window  76  displays a third-level image  82  that corresponds to the images  56  and  64 . While the second-level image  64  is transitory, since it is removed by moving the cursor  62 , the third-level image  82  will remain after the selection of a displayed stack has been incremented forward or decremented rearward. Thus, the display within the window  76  is not based upon the current display of images within the window  66 . The “loading” of an image into the window  76  can be triggered by a combination of user designations, such as cursor positioning and mouse clicking. 
     The window  78  presents a menu that is used to select the images for forming the displayed stack  50  within the window  66 . In the illustrated example, the images are stored in a folder  84  and the first-listed image (i.e., HOUSE  1 ) has been designated as the first image in the displayed stack  50 . The designated image and the following four images in the folder  84  are used to form the stack. The next five images can be used to form a “next” stack by positioning the cursor  62  in window  66  over the icon  68  for the set period of time. As an alternative, the first stack may be designated by selecting a folder in which the files are stored. Thus, by designating the folder  84 , the first image files in the folder will be used to form the stack  50 . As a user option, the selection of the image files from an image library may be arbitrary. That is, rather than a stack that directly reflects the order of files within the folder  84 , there may be a degree of randomness in the selection of files for forming the stack. 
     The window  80  may be used to transfer or organize the stored images. For example, the third-level image  82  within the window  76  may be transferred to the folder  86  in the window  80 . Drag-and-drop techniques may be used to transfer the image  82  from the window  76  or to transfer the corresponding file designation from the window  78 . However, in the preferred embodiment, the manipulation of images can occur without moving the cursor  62  from the window  66 . A combination of computer mouse operations and/or a keystroke may be used to enter one of the images  52 - 60  of the stack  50  into the folder  86 . In this application of the invention, the stack  50  is used for selecting files that are of interest to the user. The image files within a folder having a large library of images can be sorted into a number of more manageable folders by segregating the images on the basis of content (e.g., family pictures, work-related pictures, etc). Instead of sorting, the selected images may be duplicated as a result of selections triggered within window  66 . For example, the window  80  in which folder  86  resides may be a window for an auxiliary or a removable storage device. Thus, the invention may be used for its browsing-selection capability in addition to its browsing-viewing capability. 
     In one alternative application of the invention, the images  52 - 60  are thumbnail images of video clips. The thumbnail images can be browsed in the same manner as described with reference to the scrolling of digital photographs from a digital camera. However, when a particular thumbnail image is designated for loading into the window  76 , the video clip is automatically run in the window. 
     In another alternative embodiment, the images  52 - 60  in the stack  50  are representative of text documents. The images represent display information for the different text documents. This browsing approach is particularly useful if the text documents include banners or other features that distinguish one document from another. 
     The operations of the invention will be described with reference to  FIGS. 4 ,  5  and  6 .  FIG. 5  is an example of a process flow of steps, while  FIG. 6  is a simplification of the components for implementing the steps. At step  88 , the system detects an input from a user regarding forming a stack. 
     In  FIG. 4 , the image labeled “HOUSE  1 ” is selected from the window  78  for forming the displayed stack  50 , as indicated at step  90 . The selected image is positioned as the first image in the displayed stack. As previously noted, the user input may be a selection of a folder rather than an image and/or may include a degree of randomness in the selection of available images for forming the stack. In  FIG. 6 , the images are stored in the image source  92 . The source may be a hard drive of a computer or may be a storage at a remote site, with the images being accessible via a network, such as the Internet. For applications in which only the windows  66  and  78  are available, the process steps may be implemented entirely within the digital camera that is used to form the images. In this embodiment, the image source  92  is the memory of the camera. 
     At least one central processing unit (CPU)  94  is used to execute the necessary instructions. The CPU is connected to a program  96 , which is stored in non-volatile memory. The user input device  98  may be any one of or a combination of known devices for manipulating a cursor, such as a computer mouse, a trackball or a keyboard. The graphical user interface of  FIG. 4  is presented on a display device  100 , such as a monitor. 
     The movement of a cursor across the display device  100  is tracked by the CPU  94 , as indicated at step  102  in FIG.  5 . As a result, the system will be able to detect when the cursor  62  of  FIG. 4  is positioned over one of the images  52 - 60  in the stack  50 . When the cursor is positioned over one of the images, the transitory second-level image  64  is presented. This display step  104  allows the user to efficiently browse through the images. 
     The use of the window  76  is not critical to the invention. If the third-level image  82  is desired, the process includes a decision step  106  of determining whether an image has been selected. One acceptable mechanism for selecting the image may be “clicking” the computer mouse that controls the cursor  62 . The selection of an image generates the third-level image  82 , as indicated at step  108 . The selection may also be used to duplicate or move the image file to another folder, to print the image, or to otherwise manipulate the selected image or image file. The method also includes the step  110  of detecting when the user has generated a command to change the stack. The command may be a result of selecting another image from the window  78  or may be the result of using the incrementing icon  68  or the decrementing icon  70 . As previously described, merely by positioning the icon  62  over the incrementing icon  68 , a transitory image is formed for each of the first-level images  52 - 60  in the stack  50  before the stack is substituted at step  112  to present a different subset of images that will be scrolled with respect to generating the transitory images. In such a sequence, the step  104  of displaying the transitory images on the basis of cursor location results in all of the transitory images being generated as a result of the location of the cursor on the incrementing icon  68 . 
     As will be well understood by persons skilled in the art, the sequence of steps shown in  FIG. 5  may be varied without diverging from the invention. Moreover, the diagonal arrangement of images  52 - 60  in the stack  50  of  FIG. 4  is not critical. Any other overlapping arrangement that conserves display real estate may be substituted. However, an advantage of the diagonal arrangement is that the cursor  62  may be moved in a straight line to sequentially generate a transitory image for each one of the first-level images. 
     While the invention has been described primarily with respect to browsing image files within a computer or digital camera, applications within other equipment have been contemplated. For example, the graphical user interface may be a liquid crystal display (LCD) of a digital printer having a number of documents that are stored in memory. The images that represent the documents may be the first-level images that are browsed in the manner described with reference to  FIGS. 1-6 . As the first-level images are browsed, second-level transitory images are presented. Selecting a particular image causes the corresponding document to be identified as the document to be printed. 
     In another contemplated embodiment, the invention is used to browse through computer windows. The conventional approach is illustrated in  FIG. 7. A  display  114  shows four opened windows  116 ,  118 ,  120  and  122 . In a lower portion of the display  114  are five icons  124 ,  126 ,  128 ,  130  and  132 . Each icon  124 - 132  corresponds to an open window. Five icons are present, but only four open windows are shown, since one window is entirely covered by the apparent windows. In the display of  FIG. 7 , the “forward” window is window  116 . However, by clicking on any one of the five icons, the corresponding window is moved to the “forward” position. This procedure works well if the information on the icons easily distinguishes one window from the other windows and when the number of open windows is sufficiently low that the information on the icons is apparent. As the number of open windows increases, the available spacing for the icons decreases. 
     Referring now to  FIG. 8 , in accordance with this embodiment of the invention, a window-browsing region  134  of a display  136  includes display information for the various open windows. Thus, the window  138  that was not apparent in  FIG. 7  is represented in the window-browsing region  134  of FIG.  8 . In fact, it is this window that is indicated by the hovering of the cursor  140 , so that a transitory second-level image  142  is formed for the window  138 . By selecting the first-level image in the stack  144 , the window  138  is moved to the “forward” position within the display  136 . This provides an easily manipulated process for identifying the open windows and selecting one of the windows. 
     As an alternative embodiment of  FIG. 8 , the movement of the cursor  140  over one of the icons in the stack  144  may automatically move the corresponding window  116 - 122  to the “forward” position within the display  136 . That is, the transitory window  142  is not critical. In another application, the stack  144  of icons within the window-browsing region  134  represents display information for documents or applications which have not been opened. Thus, the icons within the stack  144  may be display information for various applications within a “Start” list or may be documents that are available using a particular program, such as a word processing program.

Technology Category: 3