Patent Document

BACKGROUND 
     For many years vendors of reproducible media have been concerned with unauthorized duplication of media products such as music recordings, computer software, and published works, to name several. Early software producers employed anti-copy techniques including “bad sectoring” which employed a corrupt segment in a delivered original. More recently, validation codes have been employed to register a machine specific hash with a particular installation of an operating system to ensure each delivered copy of physical media was installable on a single machine. Movie producers at one time feared that home video recorders would cause the demise of the motion picture industry, and began generating “uncopyable” tapes which would play acceptably but not generate a recordable signal for other machines to copy. 
     Mechanisms evolved to identify unauthorized or undesired propagation and distribution of media items. The study of steganography encompasses the practice of hidden or obscured messages in printed and visible works, and includes outright cryptography and other ciphers which render the media unintelligible. Unlike cryptography, however, steganographic techniques in general do not necessarily obliterate the underlying media item, and therefore does not draw attention the way encryption does. Therefore, while steganographic implementations may inject either readily visible or more obscured artifacts in the underlying media item, they generally do not prohibit intelligible reception by the user, but rather continue to merely denote the source or origin of the media item. 
     SUMMARY 
     Conventional Document Rights Management (DRM) systems include provisions for identifying the origins of instantiations of particular media item, such as a document, song, or video clip/movie. Techniques known as watermarking, already widespread to prevent unauthorized duplication of financial instruments such as checks and currency, are also employed in an electronic context. For publishers of document based materials, watermarks gained popularity as a mechanism of deterring unauthorized duplication. Once employed only for physical copies of government issued instruments, such as drivers licenses and currency, the concept has been adapted for electronic media. A watermark is an embedded token in a document to identify the origin of the particular copy or instantiation. While a watermark may be visible or hidden, a common premise is that substantial effort is required for duplication of the content without also duplicating the watermark. Hence, the watermark is carried with successive instantiations to maintain the tie to the original source. Visible watermarks are visible in a rendered copy, often as a diagonal half tone phrase or insignia across a rendered area. 
     In a particular configuration employing an encoded origin designator as disclosed herein, a content server is available to potential purchasers as a bookserver. Internet content providers such as Amazon® and Barnes and Noble® provide electronic versions of book documents, and also allow sampling by rendering selected subsets of the media item. From a provider standpoint, electronic sales are desirable, however the provider benefits from a DRM that can provide assurances that wrongfully disseminated copies of a particular media item were not attained through a breach of the providers DRM. Frequently, such unfortunate discoveries may emanate from a disgruntled publisher accusing the content provider of contributory infringement. In such a scenario, the provider has only the wrongfully obtained copy (file) from which to show that it&#39;s DRM was not breached. The disclosed watermark that is both unrenderable and hidden serves this purpose. 
     Publishers of large volumes of documents often employ a such document rights management (DRM) system for managing watermarks and other mechanisms for denoting and tracking the origin of a document or other media item to identify subsequently rendered copies, often as a deterrent to unauthorized distribution. Invisible watermarks are beneficial because they are difficult to verify “stripping” of the watermark, thus not alerting the unauthorized copier that they have successfully broken the DRM system. Further, appearance of subsequent copies are easier to trace to sources if the invisible watermark remains, while visibly renderable watermarks are easier to strip and verify, leaving subsequent copies agnostic to the source. 
     Unfortunately, conventional DRMs suffer from the shortcoming that identification of inappropriately duplicated instantiations relies on physical changes to the rendered output. Conventional steganography techniques purport to provide instantiation specific markings by making subtle, minute changes to the rendered version. For example, a particular conventional mechanism adds vertices to a rendered figure either by breaking existing vertices into multiple segments which add to the original vector, or by overwriting a vector or portion with a similar vector such that the appearance is the same. Conventional mechanisms also include so-called “jittering,” which displaces vertices a small increment such that the vector position is slightly different but the visual perception is sufficiently small to avoid detection. However, such approaches alter the physically rendered version, whether on screen or paper medium, and can cause subsequent inconsistencies with the physically rendered instantiation. Configurations herein are based, in part, on the observation that certain attributes of a display object in a media item may be manipulated or assigned a value to result in the display object being completely undisplayed. 
     Accordingly, configurations herein substantially overcome the shortcomings of conventional watermarking and other DRM identifiers by defining an unrenderable origin designator (designator) in a media item that does not display or alter the physically rendered version of an instantiation of the media item. In other words, the unrenderable designator does not appear as an obscured or occluded feature in a printed or displayed versions; rather the rendered version is unaffected by the unrenderable designator because it does not result in any displayable features. The unrenderable designator is stored in a display list of the media item and appears as an attribute of objects such that the function to cause the display object to be undisplayable, or unrenderable, are not immediately apparent. 
     In further detail, in accordance with the claimed approach, the DRM system encodes a designator in an attribute of a display object, in which the display object is configured for rendering according to a media rendering format such as PDF® (Portable Document Format, marketed commercially by Adobe® Systems Incorporated, of San Jose, Calif.), and invokable with a suitable rendering application for generating a user visual display of the display object. The DRM system adds or inserts the attribute having the encoded designator into a display object in a display list of a media item, such that the display list includes a set of display objects and each display object has a list of attributes. The rendering application is responsive to the attributes for rendering each of the display objects in a rendered form of the media item, such that the designator causes the display object having the designator to be unrenderable by the rendering application and is further indicative of the origin of the media item. A subsequent attempt to render the media item having the encoded origin designator invokes the rendering application for rendering the media item, and iterates through each of the display objects of the media item. Since the unrenderable display object having the encoded origin designator (designator) has no effect on the rendering of the media item in the rendering area, the rendering application omits changes in the rendered display resulting from the display object having the designator, but he designator is nonetheless detectable by DRM logic to identify the origin of the copy. 
     Alternate configurations of the invention include a multiprogramming or multiprocessing computerized device such as a workstation, handheld or laptop computer or dedicated computing device or the like configured with software and/or circuitry (e.g., a processor as summarized above) to process any or all of the method operations disclosed herein as embodiments of the invention. Still other embodiments of the invention include software programs such as a Java Virtual Machine and/or an operating system that can operate alone or in conjunction with each other with a multiprocessing computerized device to perform the method embodiment steps and operations summarized above and disclosed in detail below. One such embodiment comprises a computer program product that has a computer-readable storage medium including computer program logic encoded thereon that, when performed in a multiprocessing computerized device having a coupling of a memory and a processor, programs the processor to perform the operations disclosed herein as embodiments of the invention to carry out data access requests. Such arrangements of the invention are typically provided as software, code and/or other data (e.g., data structures) arranged or encoded on a computer readable medium such as an optical medium (e.g., CD-ROM), floppy or hard disk or other medium such as firmware or microcode in one or more ROM, RAM or PROM chips, field programmable gate arrays (FPGAs) or as an Application Specific Integrated Circuit (ASIC). The software or firmware or other such configurations can be installed onto the computerized device (e.g., during operating system execution or during environment installation) to cause the computerized device to perform the techniques explained herein as embodiments of the invention. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The foregoing and other objects, features and advantages of the invention will be apparent from the following description of particular embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. 
         FIG. 1  is a context diagram of a managed application environment suitable for use with the present configuration; 
         FIG. 2  is a flowchart of an encoded origin designator processing example in the environment of  FIG. 1 ; 
         FIG. 3  is a block diagram of encoded origin designator usage in the environment of  FIG. 1 ; and 
         FIGS. 4-6  are flowchart of media item rendering using the encoded origin designator of  FIG. 3 . 
     
    
    
     DETAILED DESCRIPTION 
     A document rights management system manages information relating a disseminated instantiation (copy) of a document with the origin of that instantiation. The identity of the origin is often expressed as an encoded origin designator such as a watermark that identifies the origin without significantly obscuring the identified document, but that is difficult to remove without affecting the appearance of the rendered document. Various document formats, such as PDF®, MSWord® and Wordperfect® may include an encoded origin designator, as well as other visibly renderable media such as graphical displays, slide presentations, and video. Disclosed below are an example usage of the encoded origin designator in a PDF document distributed in a managed application environment as part of a DRM implementation. In the particular configuration discussed herein, PDF files are particularly amenable to this process because the display list corresponding to the rendered PDF is rather dense and a display object with an unrenderable feature does not draw undue attention amid other display objects, hence it is difficult for a would-be copier to identify the watermark (designator) as such. 
       FIG. 1  is a context diagram of a managed application environment  100  suitable for use with the present configuration. Referring to  FIG. 1 , the managed application environment  100  includes a server  110  coupled to a network  130  for delivering media items from a repository  120 . The server  110  and repository  120  may be collocated on the same node or may be remote via the network  130 ; the network  130  may be any suitable mechanism for internode interconnection such as the Internet, LAN, WAN, WiFi, or any other suitable network infrastructure. The server  110  is invoked by a user device  140  for delivering and/or rendering a media item  152 , such as a document, slide show, movie, song, or other electronic media item adapted for delivery via the network  130 . The media item  152  includes an encoded origin designator  150  for identifying the origin of the media item  152 , discussed further below. The user device  140  includes a rendering area  142 , typically a video screen, for displaying rendered objects  144  from the media item  152  such that they are viewable by a user  146 , shown by dotted line  148 . The rendering area  142 , as applied in the example herein, illustrates a visual perception mode for exemplifying embodiments of the encoded origin designator claimed herein, however alternate rendering mechanisms such as audio may be applicable as well. 
     Configurations herein employ the encoded origin designator  150  (designator) for specifying the entity from which the media item  152  emanated, which may be the server  110  or may be a prior originator in a chain of propagation. Generally, however, it is difficult to reproduce the media item  152  without also reproducing the encoded origin designator  150 , thus the designator  150  serves as a perpetual indication appurtenant to the media item  152 . Such an encoded origin designator  150  is often manifested in a so-called watermark, an artifact that does not occlude the viewable media to which it is affixed. While some watermarks are visible to the casual viewer in a non-intrusive manner with the media item  152 , the designator  150  is carried with the media item  152  in a manner that it is not rendered with the media item  152 , however is detectable upon inspection by a predetermined detection mechanism, now discussed with respect to  FIGS. 2-6 . 
       FIG. 2  is a flowchart of an encoded origin designator  150  processing example in the environment of  FIG. 1 . Referring to  FIGS. 1-3 , the method for implementing the encoded origin designator  150  includes encoding the designator  150  in an attribute  158  of a display object  156  ( FIG. 3 , below), in which the display object  156  is configured for rendering according to a media rendering format such as PDF, as depicted at step  200  The media rendering format is invokable with a rendering application  170 , such as a PDF reader or other suitable application depending on the format, in which the rendering application  170  is for generating a user visual display of the display object in the rendering area  142 . 
     The server  110  inserts the attribute having the encoded designator  150  into a display object  156  in a display list  154  of the media item, in which the display list includes a set of display objects, as disclosed at step  201 . Each display object  156  in the display list has attributes  158 , such that the rendering application  170  is responsive to the attributes  158  for rendering each of the display objects  156  in a rendered media item  156 ′. The attributes  158  include various qualifiers and parameters based on the particular type of media item  152  being rendered. The designator  150  is selected such that it causes the display object to be unrenderable by the rendering application and is further being indicative of an origin of the media item  152 , as shown at step  202 . In the example configuration discussed further below, at least one of the attributes  158  of a display object causes it to be unrenderable, such as a zero width line or a color matching the background. The attribute itself, or other attributes of the same display object  156 , may be written with further encoded information concerning the origin. 
       FIG. 3  is a block diagram of encoded origin designator  150  usage in the environment  100  of  FIG. 1 . Referring to  FIGS. 1 and 3 , in operation, a user device  140  is invoked to render a media item  152  having an encoded designator  150  and receives the media item  152  from a source such as the server  110 . The media item  152  includes a format  153  and a display list  154  containing a list of display objects  156 - 1 . 156 -N ( 156  generally) for display in the rendering area  142  of the user device  140 . Various formats  153  define items  156 ′- 1 . 156 ′- 4  ( 156 ′, generally) including documents  156 ′- 1 , graphics  156 ′- 2 ,  156 ′- 3 , and video  156 ′- 4 . Each display object  156  has one or more attributes  158  for specifying renderable data. The rendering application  170 , such as a PDF reader, word processor, or graphics tool, parses or processes the media item  152  to attempt to render display artifacts  172  for each abject  156  as rendered display objects  156 ′ in the rendering area  142 . Each of the attributes  158  defines variables or features for physical display in the rendering area  142 . The designator  150  takes the form of attributes  158 ′ that result in the display object  156  being unrenderable, that is, not evoking a physical display on the rendering area  142  when processed by the rendering application  170 . 
     In a document rights management environment, would-be copiers often attempt to obliterate a watermark or other origin indicator to enable unauthorized distribution of copies without the copies bearing signs of origin. One particular feature of the unrendered designator  150 ′ is obscuring the designator  150  in the display list  154  such that it appears similar to other neighboring display objects  156  and is not readily apparent by inspection of the display list  154 . For example, in a display list of a PDF file, attributes  158  often take the form of a text list of attribute names followed by digit values  180 . A zero value for a line width or a color value that matches the background appears generally similar to other attribute names and values in the typically lengthy display list  154 . The unrendered designator  150  is included in attributes  158 ′, such as numeric positions, color and line specifiers, that are similar to other attributes  158  including renderable values. Therefore the unrendered designator  150 ′ may take the form of a zero width line  150 ′- 1 , or a FIG.  150 ′- 2  having a color matching the background, shown as dotted lines  150 ′- 1 ,  150 ′- 2  indicative of where the display object would be rendered but for the designator  150  represented by the unrenderable attribute. Since the unrenderable attribute  158 ′ causes the entire display object  156  to be unrenderable, an encoded string of values  180  may be written to designate additional details about the origin, for example contractual details about the particular instantiation 
       FIGS. 4-6  are a flowchart of media item  152  rendering using the encoded origin designator of  FIG. 3  in a DRM system. Referring to FIGS.  1  and  3 - 6 , at step  300 , the DRM server  110  encodes the designator  150  in an attribute  158  of a display object  156 , in which the display object  156  is configured for rendering according to a media rendering format  153 . The media rendering format  153  is invokable with a rendering application  170  for generating a user visual display of the display objects  156  in the rendering area  142 . The display object  156  may have a plurality of attributes  158 , as shown at step  301  including an attribute indicative of the origin, as shown at step  302 , an attribute causing the display object to be unrenderable, as shown at step  303 , and an attribute such that the encoded designator  150  has a visually imperceptible effect on the rendered image  156 ′, as depicted at step  304 . 
     The designator  150 , as indicated above, may have a simple range of values that merely tag the media item  152 , or may be part of a more complex origin identification scheme as in a DRM. Accordingly, a check is performed, at step  305 , to determine if multiple attributes for the display object  156  are affected by a designator  150 . If multiple attributes  158  are affected, as depicted at step  306 , the display object has a second (and possibly additional) attributes having a designator  150  indicative of an origin of the media item  152 . In such a scenario, the second attribute may be interpreted by the rendering application  170  as a null operation causing the rendering application to process the display object as a null display object that is not displayed in a rendered form  150 ′ of the media item  152 . If the DRM encoding scheme calls for a value string  180 , for example, a single attribute  158  may not have a broad enough range of values to encompass the encoded value string  180 . However, since a single unrenderable attribute  158 ′ results in the entire display object  156  being unrenderable, other attributes  158  are then available to store the value  180  for the encoded designator  150 . In such an approach, the designator  150  may be a watermark in a DRM system, such that the encoding is defined according to a predetermined set of rules of the DRM, as depicted at step  307 . Otherwise, at step  308 , the display object  156  may define a vector graphic item or other simple artifact  172 , such that the vector graphic having a zero width or background color. 
     The server  110  inserts or writes the attribute  158 ′ having the encoded designator  150  into a display object  156  in a display list  154  of a media item  152  prior to dissemination to a user, as shown at step  309 . The display list  154  typically includes a set of display objects  156 -N, such that each display object  156  has attributes  158 , in which the rendering application  170  is responsive to the attributes  158  for rendering each of the display objects  156  in a rendered media item  156 ′. In the example configuration, the encoded designator  150  appears among many attributes  158  in the display list  154 , thus avoiding detection via casual inspection, while the designator  150  nonetheless causes the display object  156  to be unrenderable by the rendering application  170  and further is indicative of the origin of the media item  152 , as depicted at step  310 . 
     Following dissemination of the media item  152  through typical channels, such as a website sale, transmission, or physical media distribution, an end user  146  invokes the rendering application  170  for rendering the media item  152  on the user device  140 , as depicted at step  311 . The rendering application  170  performs processing by iterating through each of the display objects  156  in the display list  154  of the media item  152 , as shown at step  312 . Upon attempting to render a display object  156  having the designator  150 , the rendering application  170  omits any changes in the rendered display resulting from the display object  156  having the designator  150 , as depicted at step  313 . 
     As indicated above, one or more of the attributes  158 ′ is such that the display object  156 - 2  (in the example shown) is not shown or visible on the rendering area  142 , thus the unrenderable display object  156  has no effect on the rendering of the media item  152  in the rendering area, as disclosed at step  314 . 
     In the example shown, the attribute  158 ′ may specify at least one of a zero width line and a transparent color, such that a rendering attempt occurs without making visible changes to the rendered form  150 ′ of the media item  152  resulting from the display object  156  having the designator  150 , as depicted at step  315 . The rendering application  170  therefore generates the same rendered image based on the display object  156  prior to insertion of the encoded designator  150  as following insertion of the encoded designator  150 , as depicted at step  316 . In other words, the rendering application  170  generates a visually similar rendered image  156 ′ based on the display object  156  following insertion of the encoded designator  150  as prior to inclusion of the encoded designator  150  due to the unrenderable, or nullification effect, of the attribute  150  which causes a zero width line, background color field, or other visual attribute having such an effect, as disclosed at step  317 . 
     Origin identification of instantiations (copies) is performed by comparing the designator  150  in the display list  154  to a set of matching designators  190  for determining if the origin corresponds to a predetermined origin, as depicted at step  318 , such that the set of matching designators  190  is based on a mapping of designators  150  to document origins, such as those provided from the DRM system  192 . In the example arrangement, the set of matching designators  190  is therefore based on a DRM system for identifying propagated instantiations of the media item, as disclosed at step  319 . Upon subsequent comparison, at step  320 , if a match is found, then the DRM system  192  or rendering application  170  decodes the designator  150  and identifies the origin. Alternatively, a lack of a matching designator indicates no watermarking or origin designation recognized by the DRM  192 , as depicted at step  322 . 
     Those skilled in the art should readily appreciate that the programs and methods for encoding origin designators as defined herein are deliverable to a user processing and rendering device in many forms, including but not limited to a) information permanently stored on non-writeable storage media such as ROM devices, b) information alterably stored on writeable storage media such as floppy disks, magnetic tapes, CDs, RAM devices, and other magnetic and optical media, or c) information conveyed to a computer through communication media, as in an electronic network such as the Internet or telephone modem lines. The operations and methods may be implemented in a software executable object or as a set of encoded instructions for execution by a processor responsive to the instructions. Alternatively, the operations and methods disclosed herein may be embodied in whole or in part using hardware components, such as Application Specific Integrated Circuits (ASICs), Field Programmable Gate Arrays (FPGAs), state machines, controllers or other hardware components or devices, or a combination of hardware, software, and firmware components. 
     While the system and method for encoding origin designators has been particularly shown and described with references to embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims.

Technology Category: 5