JP2004531000A - Method and system for manipulating graphic information - Google Patents

Abstract

The operation of the graphic information is executed according to the computing device on which the graphic information is to be displayed. The capabilities of the computing device are used to construct a set of constraints on the graphical information obtained from the content provider. These constraints take into account factors such as the display characteristics, processing power, available memory, and communication capabilities of the computing device. The graphical information is manipulated to meet a set of constraints, resulting in graphical information that can be displayed and interpreted by the computing device.
[Selection] Figure 2

Description

【Technical field】
[0001]
The present invention is directed to manipulating graphic information according to the characteristics of a device for displaying graphic information.
[Background Art]
[0002]
With the diversification of computing devices capable of displaying graphical information, the demand for providing such information in a format that can be interpreted by each computing device has increased. As a result, various forms of graphic information have been developed, and a wide variety of graphic information has often been provided for each format. The resulting format is often far from optimal for each computing device, resulting in complications such as the need to convert the graphics information to a different format during the development of the graphics information. . This different and distinct form does not take into account features of the computing device, such as display characteristics, processing power, available memory, and communication capabilities.
DISCLOSURE OF THE INVENTION
[Problems to be solved by the invention]
[0003]
The problem to be solved by the invention is that the different and distinct forms do not take into account the capabilities of the computing device, such as display characteristics, processing power, available memory, and communication capabilities.
[Means for Solving the Problems]
[0004]
According to one aspect of the present invention, a method of modifying graphical information to be displayed on a computing device having a set of display characteristics representative of a display function of the computing device includes displaying the graphical information characteristics with a set of display characteristics. A method comprising determining a manner of adapting the characteristic and matching the characteristic of the graphic information with a set of display characteristics according to the scheme to provide the graphic information in a format adapted to the display of the computing device. Provided.
[0005]
According to another aspect of the invention, a system for modifying graphical information to be displayed on a computing device having a set of display characteristics representative of a display function of the computing device, wherein the characteristic of the graphical information is modified by one. A matching mechanism for evaluating a set of display characteristics and the characteristics of graphic information to determine a method to be adapted to the set of display characteristics, and a matching mechanism for harmonizing the characteristics of graphic information with the set of display characteristics in accordance with the method. A system is provided that includes a graphics modification mechanism and a controller for adjusting the modification of the graphics information to provide the graphics information in a format adapted for display on a computing device.
[0006]
According to yet another aspect of the present invention, computer-executable instructions for modifying graphical information to be displayed on a computing device having a set of display characteristics representative of a display function of the computing device are stored. The computer-executable instructions, wherein the computer-executable instructions determine how to adapt the characteristics of the graphical information to a set of display characteristics, and provide the graphical information in a form adapted for display on a computing device. A computer-readable medium is provided that includes matching the characteristics of the graphical information with a set of display characteristics according to the method.
[0007]
Other aspects and features of the present invention will become apparent to one with skill in the art upon examination of the following description of specific embodiments of the invention in conjunction with the accompanying drawings.
BEST MODE FOR CARRYING OUT THE INVENTION
[0008]
The present invention will be described with reference to the drawings.
FIG. 1 and the associated description illustrate one example of a suitable computing environment 10 in which the invention may be implemented. Although the invention will be described in the general context of computer-executable instructions of a computer program, the invention may be implemented in combination with other program modules.
[0009]
Generally, program modules include routines, programs, components, data structures, etc. that perform particular tasks or implement particular abstract data types. Further, the present invention provides for handheld devices, multiprocessor systems, multiprocessor-based or programmable consumer electronics, minicomputers, mainframe computers, and program modules on local and remote storage devices. Other computer system configurations, including distributed computing environments that may be deployed, may be used or implemented in combination therewith.
[0010]
Referring to FIG. 1, the present invention provides a conventional computer 12 including a processing unit 30, a system memory 14, and a system bus 34 coupling various system components including the system memory 14 to the processing unit 30. It can be implemented on a general purpose computing device of the type. The system memory 14 includes a read-only memory (ROM) 16 and a random access memory (RAM) 20.
[0011]
A basic input / output system 18 (BIOS) containing basic routines useful for transferring information between elements within computer 12 (e.g., during start-up) is stored in ROM 16. The computer 12 may be a hard disk drive 38 for reading / writing to / from a hard disk (not shown), a magnetic disk drive 42 for reading / writing to / from a removable magnetic disk 72, a CD ROM or other optical media. Also includes an optical disk drive 46 for reading / writing from / to the removable optical disk 70, all of which are connected to the system bus 34 by respective interfaces 36, 40, 44. Drives 38, 42, 46 and associated computer readable media 72, 70 provide non-volatile storage of computer readable instructions, data structures, program modules, and other data for computer 12. Although the example environment described herein utilizes a particular disk, it should be understood by those skilled in the art that other types of computer readable media for storing data may be utilized.
[0012]
Storing a plurality of program modules on disks 72, 70, ROM 16 or RAM 20 containing operating system 22, one or more application programs 24, other program modules 76, and program data 74. Can be. Commands and information may be input to personal computer 12 by input devices (eg, keyboard 64, pointing device 68, microphone, joystick, etc.). These input devices can be connected to the processing unit 30 by a serial port interface 48, a parallel port, a game port, or a universal serial bus (USB). A monitor 52 or other type of display device may also be connected to the system bus 34 via an interface such as a video adapter 32.
[0013]
Computer 12 may be one such as another personal computer, handheld device, minicomputer, miniprocessor-based or programmable consumer electronics, or other device capable of displaying graphical information. Alternatively, it operates in a networked environment using logical connections to multiple remote computing devices 56. The logical connection shown in FIG. 1 is a communication network 54, which may be a wireless network, a packet switched network, or the like.
[0014]
The computer 12 is connected to a communication network 54 via a communication module 50. The operation of the present invention can be distributed between the two computers 12, 56 such that one acts as a server and the other acts as a client (see FIG. 2). The operation of the present invention for each computer 12, 56 (client and server) may be stored in the RAM 20 of each computer 12, 56 as an application program 24, another program module 26, or on a disk 38, 42, 46. They can be stored in one. It will be appreciated that the network connections shown are exemplary and other means of establishing a communication link between the computers may be used.
[0015]
FIG. 2 illustrates a graphics manipulation system 110 for manipulating graphics information to be displayed on a remote computing device 56 according to an embodiment of the present invention. Graphical information can include, for example, text, icons and other images, graphical user interfaces, and the like. The graphics manipulation system 110 includes various components of the computer 12, including the application program 24, other program modules 26, program data 28, RAM 20 or other disks 72, 70, the communication interface 50, and the processing unit 30. Can be implemented. The graphics manipulation system 110 converts the graphics information into a format that can be used and understood by the remote computing device 56 to display the graphics information obtained from a graphics server (not shown). Converting the graphical information is similar to customizing the graphical information according to the device on which it is displayed, ie, the remote computing device 56. This customization can take into account the display, transmission, and processing capabilities of the remote computing device 56.
[0016]
Remote computing device 56 requests graphical information to be displayed. A request for graphic information can be sent directly to the graphic operation system 110, and the graphic operation system 110 retrieves the graphic information from the graphic server via the communication network 54. The graphics server can be any computing device that can obtain graphics information, such as a web server, a database server, and the like. Alternatively, the remote computing device 56 can request graphics information from a graphics server, which requests manipulation of the graphics information by the graphics manipulation system 110.
[0017]
The graphic information is then provided to the remote computing device 56 directly from the graphic manipulation system 110 or via a graphic server. The embodiment of FIG. 2 shows a case where the graphic information is requested from the graphic operation system 110 and the graphic information is received therefrom.
[0018]
The remote computing device 56 can be any device having a display unit 102, a communication module 108, and a graphic interpreter 104 with a data storage device 106. Remote computing device 56 may be, for example, a desktop computer, a handheld computer, a personal digital assistant (PDA), a portable / cellular phone with a display, and the like. The communication module 108 requests and receives graphic information from the graphic operation system 110. Communication between the remote computing device 56 and the graphics manipulation system 110 may be wireless communication means, a network connection such as a local area network, or a physical link (eg, resident on the same physical computing entity or Is a logical connection that can be through a communications network 54, such as a remote computing device 56 in close proximity to the graphics manipulation system 110). The graphic interpretation mechanism 104 interprets the graphic information received from the communication module 108 to display the graphic information on the display unit 102. Graphic interpretation involves recognizing objects such as various geometric shapes (eg, lines, circles, polygons, etc.) and / or compound effects (eg, anti-aliasing, translucent, etc.), and recognizing the recognized objects. It may need to be generated on the display unit 102.
[0019]
The graphics manipulation system 110 communicates with the remote computing device 56 via the communication module 50. Communication module 50 receives a request for graphical information from remote computing device 56. If the graphic information is already adapted for display by the remote computing device 56, the communication module 50 transfers the graphic information to the remote computing device 56 in response to the request. Although only a single remote computing device 56 is shown in FIG. 2, those skilled in the art will appreciate that the communication module 50 can respond to requests for multiple remote computing devices 56 of various types.
[0020]
The controller 120 of the graphic operation system 110 is responsible for adjusting and managing the achievement of the request for the graphic information.
The request analysis mechanism 126 of the controller 120 extracts various components included in each request for graphic information. Each request made to the graphic information includes the location of the graphic information (eg, address of the graphic server), the identification information of the graphic information, and the characteristic information of the remote computer device 56. The characteristic information is an overview of the functions of the remote computing device 56 and includes information such as the type of device, amount of available memory (heap and storage), data transmission speed, processing speed, and display characteristics. be able to. Display characteristics include display size, color system, color depth, screen resolution (eg, dots per inch), valid word / byte order (eg, big endian, little endian), and basic shape, Specific image interpretation features such as support for complex shapes, bitmaps, effects, paint, strokes, etc. can be included. This information constitutes a device profile used to convert the graphical information into a format customized to the capabilities of the remote computing device 56. The extracted components of the request (ie, the location and ID of the graphical information and characteristic information about the remote computing device 56) are provided to the customization coordinator 128 and the profile revisioner 130 for further processing.
[0021]
Characteristic information about the remote computing device 56 is used by the profile revision mechanism 130 of the controller 120 to create and maintain a device profile for the remote computing device 56 in the profile data storage 118. The profile data storage device 118 contains a profile for a device that requests graphic information from the graphic operation system 110. A profile for a device can include information such as device type, amount of memory, data transmission speed, processing speed, and display characteristics.
[0022]
The profile revision mechanism 130 extracts the device type information from the property information and determines whether a profile for the device currently exists in the profile data storage 118 for the given device type. If a profile for a given device type currently exists, the profile revision mechanism 130 may store the profile data in the profile data storage 118 according to the difference between the device profile in the profile data storage 118 and the characteristic information of the request. Revise some information. If a profile for the device does not exist in the profile data storage, the profile revision mechanism 130 creates one profile based on the characteristic information of the request.
[0023]
The customization coordinator 128 of the controller 120 manages the fulfillment of the request, including the conversion of the graphical information into a format adapted according to the capabilities of the remote computing device 56. The customization mechanism 128 determines whether the graphical information has been previously requested and stored and whether the requesting device is of the same type as the remote computing device 56. First, the graphic content data storage device 122 is checked. Graphic content data storage 122 may include previously obtained graphic information and / or already customized graphic information. Graphic information from the graphic content data storage device 122 is customized under the control of the customization coordinator 128 depending on the type of remote computing device 56. The graphical information in the graphical content data storage device 122 that is already customized for the type of device of the remote computing device 56 is in a form adapted to the capabilities of the remote computing device 56 and may be there upon request. Can be transferred.
[0024]
If the graphic content data storage device 122 does not include the graphic information corresponding to the requested graphic information, the position and ID of the graphic information extracted from the request are changed by the customizing mechanism 128 to retrieve the graphic information from the graphic server. used. The customization coordinator 128 has the graphical information converted into the first format and can create an abstract representation from the graphical information, which is then adapted to the capabilities of the remote computing device 56. Format.
[0025]
The graphics server interface 114 is used by the customization coordinator 128 to communicate with the graphics server for obtaining graphics information. The graphics server interface 114 contacts the graphics server at the location indicated in the request for graphics information. Next, graphic information corresponding to the identification information of the request is requested from the graphic server. The graphics server interface 114 receives the graphics information from the graphics server and provides this information to the customization adjustment mechanism 128. The graphics server interface 114 and the controller 120 cooperate to obtain graphics information.
[0026]
For graphic information that has not yet been customized (ie, from graphic content data storage 122 or a graphic server), the format of the graphic information is determined by the format identification mechanism 142. The type identification mechanism 142 obtains the graphic information from the customization adjustment mechanism 128. The format identification mechanism 142 determines the format of the graphic information (ie, bitmap, JPEG, TIFF, GIF, html, etc.) in anticipation of converting the graphic information from the current format to the first format. Type identification mechanism 142 examines graphical information to locate well-known identifiers for various types. For example, the graphic information may have a file name that can be used to indicate the format of the graphic information (eg, the file name landscape.jpg indicates that the file may be in JPEG format). ing). The type identification mechanism 142 can also inspect the type signature of the graphic information header to determine its type. Graphic information is stored in, for example, bitmap, JPEG, TIFF, GIF, scalable vector graphics (SVG), computer graphic metafile (CGM), extended metafile format (EMF), portable document format (PDF), etc. It can be in any of a number of formats.
[0027]
The graphic reformatting mechanism 124 is provided with graphic information along with information about the current format. The graphic reformatting mechanism 124 converts the format of the graphic information into a first format. The graphic reformatting mechanism 124 includes a plurality of format-specific mechanisms 132 to 140 to perform this function. Each of these format-specific mechanisms 132-140 is dedicated to the current format of graphic information. For example, the bitmap mechanism 132 converts graphic information in a bitmap format into a first format, the TIFF mechanism 134 converts graphic information in a TIFF format into a first format, and the JPEG mechanism 136 converts graphic information in a JPEG format. The first format is converted, and the GIF mechanism 138 converts graphic information in the GIF format into the first format. Each of the mechanisms 132-140 may be any of a number of well-known file format conversion mechanisms. In this way, a plurality of types of graphic information can be converted into a single format, that is, the first format. The graphic information of the first format is provided from the graphic reformatting mechanism 124 to the customization adjusting mechanism 128. The first form should represent most of the vector graphics, bitmap graphics, and document formats of graphics information. The first form of grammar should efficiently store graphic information and also allow for the representation of graphic information to be manipulated, and should also allow for simple construction of abstract representations of graphic information. The first format may be, for example, a vector based on the W3C Scalable Vector Graphic Specification, CGM, PDF, etc.
[0028]
The graphic abstraction mechanism 116 receives the first form of graphic information from the customization adjustment mechanism 128 and creates an abstract representation of the graphic information. The abstract expression represents each entity of the graphic information as an object, and indicates a relationship between different objects. For example, all information about the circle and its display, such as size, filling, line thickness, etc., can be considered as objects. The abstract representation can take the form of a tree, for example. The first form should allow the construction of abstract representations. Abstract representations provide browsing of graphical information that leads to simplification, reduction, or revision of the graphical information.
[0029]
The graphic customization mechanism 112 receives an abstract representation of the graphic information from the customization coordination mechanism 128 for manipulating the form of the graphic information to be transmitted to the remote computing device 56 and formatted for display thereon. Graphic customization mechanism 112 generates graphic information in a second format that may vary depending on the type of remote computing device 56. The second type does not depend on the capabilities of the remote computing device 56 or the type of device. The manipulation of the graphical information is based on the capabilities of the remote computing device 56 as determined from the device profile in the profile data storage 118 for the type of remote computing device. The operations may also be performed to increase the speed at which the graphical information can be transmitted to the remote computing device 56 or the speed at which the graphical information is displayed on the computing device 56. The actions involved describe or verify information that cannot be displayed on the remote computing device 56 (eg, color information if the display unit 102 is grayscale) and graphical information but are not used for display purposes. This may include removing other information. The second form of graphic information can be simplified, but still maintains a visual representation similar to the original form of graphic information from the graphic server. The graphic customization mechanism 12 functions to evaluate the operation to be performed and then match the graphic information with the capabilities of the remote computing device 56 to adapt the graphic information to a form adapted to the capabilities of the remote computing device 56. I do.
[0030]
The graphic information can be stored in the graphic content data storage device 122 by the customization coordinator 128 after being received from the graphic server (ie, stored in a form that is not customized to the type of device). The graphic information can also be stored in the graphic content data storage 122 by the customization adjustment mechanism 128 after being converted to the second format by the graphic customization mechanism 112.
[0031]
FIG. 3 is a system diagram of the graphic customizing mechanism 112 of the graphic operation system 110. Graphic customization controller 212 receives abstract representations and information of remote computing device profiles from customization coordinator 128 of controller 120. Graphic customization controller 212 manages the process of converting the abstract representation into a second form of graphic information based on the device profile of remote computing device 56. The second type of graphical information includes a rendering process that can be performed before being interpreted by the graphical interpreter 104 of the remote computing device 56.
[0032]
Information on the remote computing device profile is provided by the graphic customization controller 212 to the profile interpreter 214. The information in the remote computing device profile may be a device profile, such as stored in profile data storage 118, or sufficient for profile interpreter 214 to retrieve the device profile from profile data storage 118. It may include identification information. The profile interpreter 214 interprets the device profile or characteristics of the remote computing device 56 to create a set of constraints on the graphical information returned to the remote computing device 56. That is, the profile interpreter 214 determines the capabilities of the remote computing device 56 and ensures that these capabilities are not exceeded, or that the demand for resources of the remote computing device 56 does not exceed a given threshold. (Eg, 70% of available resources, etc.). A set of constraints can include display size, file size of graphic information, display color, and the like.
[0033]
The constraints are provided to the graphic customization controller 212 to adapt the abstract representation to a set of constraints. A mechanism for adapting the abstract representation to each constraint (ie, a mechanism corresponding to each constraint) may exist in the graphic customization mechanism 112. Graphic customization controller 212 determines a series of operations that satisfy a set of constraints. This series of operations includes information on the type of conversion to be performed by each of the operating mechanisms 200 to 210 and the order in which each conversion is performed. The graphic customization controller 212 performs a series of operations by successively passing the modified abstract representation from the mechanisms 200 to 210 to each of the mechanisms 200 to 210 indicated by the series of operations. When providing an abstract representation to each mechanism 200-210, the graphic customization controller 212 also provides information regarding the type of operation to be performed.
[0034]
Each mechanism 200-210 receives an abstract representation having information about the type of operation that mechanism 200-210 is to perform. The operations may be performed in a determined order, as indicated by the graphic customization controller 212 or as determined by the mechanisms 200-210.
[0035]
The color correction mechanism 200 operates on the color, shading, and filling information of the abstract representation. Color, shading, and filling operations are performed to match the color information of the abstract representation with the functions of the display unit 102. Manipulating color information with the color correction mechanism 200 may require changing colors in the abstract representation or changing the way colors are represented. The color change in the abstract representation can be performed in order to convert the complexity of the color information of the graphic information performed by the abstract representation and to unify the color display for a plurality of pages or a plurality of files of the graphic information. The color information of the abstract expression has the same format as the color information of the original graphic information from the graphic server. If the function of the display unit 102 is different from the color information, the color information related to the abstract expression is converted into color information correlated with the function of the display unit 102. For example, if the color complexity of the abstract representation is an RGB (red-green-blue) color model and the display unit 102 displays a grayscale image, the color information of the abstract representation is converted accordingly. The color correction mechanism 200 converts arbitrary color information from the abstract representation into RGB / RGBA (alpha-red-green-blue), RGB (24 bits), RGB (16 bits), RGB (12 bits), and a palette table. Convert to any color system supported by the remote computing device, such as color system, gray scale (8 bits), gray scale (4 bits), and black and white).
[0036]
During the conversion between the complexities of the color information, the color correction mechanism 200 identifies the complexities of the color information of the abstract representation and the complexities of the color information that can be displayed on the display unit 102 shown in the device profile. The conversion between color information complexities can be performed according to any of a number of conversion algorithms known in the art.
[0037]
The conversion of the complexity of the color information can also be executed based on the function of the graphic interpretation mechanism 104. Although the display unit 102 can be configured to display any color system, the graphic interpreter 104 interprets only a limited number of all possible colors (ie, a limited color palette). I can't. The color correction mechanism 200 identifies the complexity of the color information of the abstract representation and converts it to the same color information of the display unit 102. The color correction mechanism 200 identifies the complexity of the color information of the graphic interpretation mechanism 104. The complexity of the color information for the abstract expression is limited to include only the number of colors or less in the color palette of the graphic interpretation mechanism 104. Limitations on the complexity of the abstract representation color information are well known in the art, such as building a histogram representation of the abstract representation colors and reducing the number of colors based on color frequency and color segmentation. Can be implemented according to any of a number of algorithms.
[0038]
When the graphic information is distributed over a plurality of browse pages or is derived from a plurality of files, the color display is unified. If the graphic information requested by the remote computing device 56 is in multiple files as obtained from the graphic server, each file may contain color information of different complexity. If the files remain separate, the color corrector 200 guarantees consistency between all of the separate files after performing the multiplicity conversion of the color information. Any of a number of well-known techniques for ensuring uniformity of color information among a plurality of files can be used. For example, a histogram can be generated for color information for each file, and the result of each histogram can be mapped to each file to generate a single color palette for all files. In this case, the color information for each file can be converted to fit the determined single color palette.
[0039]
If the files are merged into a single abstract representation, the color information for each file can be mapped to a single color complexity and color format before the merge.
In order to match the color information format of the abstract information with the color information format of the display unit 102, a change in the color representation method is performed. Color information can be represented in a number of different formats, including CMYK (cyan-magenta-yellow-black), RGB, HIS (hue-saturation-brightness), and CIE XYZ (International Commission on Illumination). The color correction mechanism 200 determines the color information format of the abstract expression and the color information format of the display unit 102 as indicated by the device profile. The color correction mechanism 200 converts the color information format of the abstract representation to the color information format of the display unit 102 according to any of a plurality of conversion algorithms known in the art.
[0040]
Manipulation of the shading and filling information by the color correction mechanism 200 may involve converting the shading and filling information of the abstract representation into a format corresponding to the shading and filling information indicated in the device profile. If a color, gradient (linear or radial), or pattern (vector, image, or gradient) is used, the graphic object can be filled (colored inside) or drawn (colored outline) Can have shape and text. Gradients consist of a continuous smooth color transition along a vector from one color to another, which may be followed by further transitions to another color along the same vector. There is also. Patterns and gradients can be used to fill or draw objects. The pattern can duplicate predefined graphic objects at fixed intervals in the standard x and y directions to cover the area to be colored. For example, if the graphic interpretation mechanism 104 or the display unit 102 does not have the function of displaying gradation filling or pattern filling, these fillings are converted to solid fillings. The color correction mechanism 200 receives information about shading and filling that can be displayed by the display unit 102 and the graphic interpretation mechanism 104 from the device profile and shading and filling information from the abstract representation. The shading and filling information for the abstract representation is adapted to the shading and filling functions indicated in the device profile. The transformation of the shading and filling information can be performed according to any of a number of well-known algorithms. For example, the conversion of tone fill to solid fill can be performed using the midpoint of the tone color.
[0041]
The graphic correction mechanism 202 operates the geometric representation of the object in the abstract representation. Graphic modification mechanism 202 may perform geometric operations to provide the object with a geometric shape that can be displayed by remote computing device 56. Geometric operations can include transformations in the form of curves, performing affine transformations, and transforming caps and joins.
[0042]
Transformation of a curve form in an abstract representation may involve transforming a curve segment object in a form that the remote computing device 56 cannot display and interpret into a series of straight line segment objects. The curve format conversion can also be performed to reduce the amount of data used to describe the curve object, and consequently also reduce the transmission size of the graphic information. The curve form may be, for example, a cubic Bezier, a simple cubic Bezier, a quadratic Bezier, a simple / smooth quadratic Bezier, or an elliptical arc. The graphic correction mechanism 202 determines a curve format for each curve object of the abstract representation and a curve format function indicated in the device profile. The graphic correction mechanism 202 matches the curve form of each curve object of the abstract representation to the curve form of the device profile according to any one of a plurality of curve transformation techniques known in the art.
[0043]
To prevent graphic interpreter 104 from performing this operation, graphic modifier 202 can perform an affine transformation on the abstract representation. Executing the operation and conversion before transmitting the graphic information reduces the amount of processing performed by the graphic interpreting mechanism 104 to display the graphic information. This allows the effect of using a greater amount of computing resources than is available on the remote computing device 56 to be incorporated into the graphical information before transmission to the remote computing device 56. The graphics modification mechanism 202 can be performed by any one of a plurality of affine transformation algorithms known in the art.
[0044]
Conversion of one or more cap and join forms of the abstract representation may involve converting the line cap and line join objects into a form that can be displayed and interpreted by the remote computing device 56. The line cap object, the shape used at the open sub-path end when drawing with a line, may be, for example, a bat, a circle, or a square. The shape used at the line join object, ie the corner of the path, may be, for example, a semi-right angle, a circle, or a bevel. The graphics modification mechanism 202 determines the type of each line cap and line join object of the abstract representation and one or more types that the remote computing device 56 can display and interpret as indicated in the device profile. . The graphics modification mechanism may be configured to display one or more line cap and line join forms of abstract representations that cannot be displayed and interpreted in accordance with well-known line cap and line join form modification techniques. Convert to format.
[0045]
Display adaptation mechanism 204 manipulates the abstract representation to provide graphical information that is aligned with the size of the display as indicated in the device profile. Display adaptation mechanism 204 can perform operations such as merging files, capturing scripts, and clipping the display area.
[0046]
The display adaptation mechanism 204 can incorporate a plurality of files belonging to the requested graphic information into a single abstract representation. The resulting abstract representation can span multiple pages based on the size of the display unit 102 and can include graphic information in multiple formats when received from the graphic server. If a particular single page is being requested by the remote computing device 56, the display adaptation mechanism 204 creates a separate abstract representation that includes only the requested page.
[0047]
The script function referenced in the abstract representation is determined by the display adaptation mechanism 204 to retrieve the result of incorporating the script into the script or abstract representation. Like merging files, embedding a script involves determining the result of the script and merging the result of the script into an abstract representation.
[0048]
The display adaptation mechanism 204 determines the display size of the graphic information implemented in the abstract expression and the size of the display unit 102 indicated by the device profile. The display adaptation mechanism 204 matches the display size of the abstract representation with the display size of the display unit 102. This can be achieved by reducing any raster data from the abstract representation to a size that is compatible with the remote computing device 56. The reduction can be performed according to any one of a number of techniques known in the art, such as interpolation or decimation.
[0049]
The text converter 206 converts any text object in the abstract representation into a form interpretable by the graphic interpolator 104. The graphic interpolator 104 can render this format in a stroke font format or a raster font format. The font format drawn with lines uses vectors (non-contours) and can be scaled and rotated. The raster font format uses a bitmap and scales according to integer values (eg, 2, 3, etc.) and 90 ° rotation. The text converter 206 examines all text objects in the abstract representation to determine all font types used by the graphical information. The text converter 206 provides a consistent format between different text objects and converts the format of the text object to provide a text object in a format that the graphic interpreter 104 can interpret. Conversion of text objects between formats can be performed according to any of a number of techniques well known in the art.
[0050]
Transmission size adaptation mechanism 210 operates the abstract representation to provide transmission size graphic information consistent with the communication link between graphic manipulation system 110 and remote computing device 56. That is, when the capacity of the communication link is small, the transmission size adaptation mechanism 210 reduces the transmission size of the graphic information in order to avoid a long transmission time. Based on the remote computing device profile, the transmit size adaptation mechanism 210 uses information regarding the capacity of the data storage device 106 of the remote computing device and the capacity of the communication link to determine the desired size for the graphical information.
[0051]
The abstract representation is manipulated by the transmit size adaptation mechanism 210 to provide a sufficient reduction in graphic information size. These reductions include removing redundant information, removing non-visual elements, bitmap resampling, simplifying complex shapes, reducing the resolution of graphic information, and reducing the coordinate system used to display graphic information. It can be implemented using well-known techniques, such as reducing complexity. Eliminating redundant information involves looking for objects in the abstract representation that have common properties, and grouping those objects in such a way that properties are not repetitively represented. Removing non-visual elements involves removing any objects that are not visually represented in graphical information, such as comments, empty groups, invisible shapes, shapes outside defined clipping regions, and the like. Bitmap resampling involves reducing the resolution of bitmap format graphics information to its size while maintaining acceptable visual quality. Simplifying complex shapes involves replacing complex shapes (polylines, paths, polygons, curves, etc.) with visually similar shapes (rectangles, lines, circles, etc.). Reducing the image resolution may involve reducing the portion of the graphical information in the abstract representation that is higher in resolution than can be viewed by the remote computing device 56. Reducing the complexity of the coordinate system used to represent graphical information can include, for example, converting multiple units (eg, centimeters, inches, etc.) and floating point user coordinates to integer space.
[0052]
The format conversion mechanism 208 converts the abstract representation into a format that can be interpreted by the remote computing device 56. When the abstract representation is manipulated by other mechanisms 200-210 to be in a form corresponding to the capabilities of the remote computing device 56, the abstract representation is formatted with an indication of the form that the graphic interpreter 104 can interpret. The conversion mechanism 208 is provided. The format conversion mechanism 208 performs an operation opposite to that of the graphic abstraction mechanism 116 by converting the abstract expression into graphic information, and possibly a format different from the original graphic information. The final graphic information generated by the format converter 208 should be small, simple and flexible enough to support various device types. The final form of graphical information should also support multiple geometric and graphical objects and different color systems. The final format should also support text and font information.
[0053]
4A and 4B illustrate a method 300 for manipulating graphical information with the graphical manipulation system 110 according to the remote computing device 56 for which graphical information is to be displayed. At step 302, a request for graphical information is received from a remote computing device 56. In step 304, the part of the request to provide the content is extracted. The identification information of the requested graphic information is extracted along with information about the remote computing device 56.
[0054]
At step 306, the profile data store 118 is consulted to determine if it contains a profile corresponding to the device type of the remote computing device 56. Once the corresponding device profile is found in the profile data storage 118, at step 308 the difference between the requested device information and the profile is determined. The profile is then updated at step 310 by making the information in the profile different from the corresponding information from the remote computing device 56 information from the request. If a corresponding device profile is not found in profile data storage 118, a new profile is created in step 312 based on the requested remote computing device 56 information.
[0055]
Once the profile has been created or determined, at step 314 the graphic content data storage 122 is consulted to determine if the graphic information identified in the request is present in the data storage 122. If the requested graphic information is not present in the graphic content data storage device 122, at step 316, the graphic information is requested from the graphic server identified in the request. In step 318, the requested graphic information is received from the graphic server.
[0056]
Once the graphical information is received or retrieved from the graphical content data storage device 122, a determination is made at step 320 as to whether the graphical information is in a form specific to the remote computing device 56. That is, at step 320, it is determined whether the graphic information has been customized for the remote computing device 56. If the graphic information is in a format not specified, the original format of the graphic information is determined in step 322. At step 324, the graphic information is converted from the original format to the first format. As a result, graphic information in a single format that may have originally had a plurality of formats is provided. At step 326, an abstract representation of the graphic information in the first format is created.
[0057]
At step 328, a set of constraints is determined for the graphical information implemented by the abstract representation based on the profile of the remote computing device 56. These constraints take into account the capabilities of the remote computing device 56 in areas such as display size and color, memory capacity, transmission link capacity, and the like. At step 330, a series of operations is determined that adapt the abstract representation to a set of constraints to provide graphical information that can be displayed and interpreted by the remote computing device 56. These operations are systematically performed on the abstract representation at step 332. Operations include changing the colors used in the abstract representation, changing the color representation, unifying the color representation across multiple files, converting shading and filling information, converting curve object formats, performing affine transformations, cap and join objects Operations such as format conversion, adapting the display size to the display size of the display unit 102, converting the text format, reducing the transmission size, etc., can be included. The manipulated abstract representation is converted at step 334 into a second form of graphical information that can be interpreted by the remote computing device 56.
[0058]
The second form of graphic information, whether obtained from the graphic content data storage device 122 or an operated abstract representation, is transmitted to the remote computing device at step 336.
[0059]
The operation of the graphic information according to the computing device for which the graphic information is to be displayed is executed. The capabilities of the computing device are used to construct a set of constraints on the graphical information obtained from the content provider. These constraints take into account factors such as the display characteristics, processing power, available memory, and communication capabilities of the computing device. The graphical information is manipulated to meet a set of constraints, resulting in graphical information that can be displayed and interpreted by the computing device.
[0060]
Although the methods disclosed herein have been described and illustrated with reference to specific steps performed in a specific order, these steps constitute an equivalent method without departing from the teachings of the present invention. It will be appreciated that they can be combined, subdivided, or reordered. Thus, unless otherwise indicated herein, the order and grouping of steps is not a limitation of the present invention.
[0061]
It will be apparent to those skilled in the art that many modifications and variations of the specific embodiments described herein can be made without departing from the spirit and scope of the invention.
[Industrial applicability]
[0062]
The invention described above according to exemplary embodiments applies to the industrial field of graphic information display.
[Brief description of the drawings]
[0063]
FIG. 1 illustrates an example of a suitable computing environment in which the invention may be implemented.
FIG. 2 is a system diagram of a system for operating graphic information for display according to an embodiment of the present invention.
FIG. 3 is a system diagram of a graphic customizing mechanism of the system of FIG. 2;
FIG. 4A is a flowchart illustrating a method of manipulating graphical information for display according to one embodiment of the present invention.
FIG. 4B is a flowchart illustrating a method for manipulating graphical information for display according to one embodiment of the present invention.

Claims (35)

A method of modifying graphical information to be displayed on a computing device having a set of display characteristics representing a display function of the computing device, the method comprising:
Determining a method of adapting the characteristics of the graphical information to a set of display characteristics;
Reconciling the characteristics of the graphical information with the set of display characteristics in accordance with the scheme to provide the graphical information in a format adapted to the set of display characteristics. Before the decision step,
Receiving a request for modification of the graphical information, the request comprising an indication of a set of display characteristics of the computing device;
Obtaining graphical information according to the request. 3. The method of claim 2, wherein the method is based on the indication of a set of display characteristics of the request. The method of claim 1, further comprising converting the graphic information to a first format before reconciling the characteristics of the graphic information. The method of claim 4, further comprising creating an abstract representation of the graphical information in a first format suitable for facilitating creation of the abstract representation. The method of claim 5, wherein determining comprises using the abstract representation to determine a characteristic of the graphical information. The deciding step is
Determining a set of graphical display constraints for the computing device based on the set of display characteristics;
Determining a set of operations that adapts the characteristics of the graphic information to the set of graphic display constraints;
Constructing the scheme to apply each operation of the set of operations to the abstract representation in a predetermined order;
The step of harmonizing
Applying the method to the graphic information by applying each operation of the set of operations to the abstract representation in the predetermined order to provide graphic information adapted to a set of display characteristics. The method of claim 6. The deciding step is
Determining a set of graphical display constraints for the computing device based on the set of display characteristics;
Determining a set of operations that adapts the characteristics of the graphic information to the set of graphic display constraints;
Constructing the scheme to apply each operation of the set of operations to graphic information in a predetermined order. The harmonizing step applies the method to the graphic information by applying each operation of the set of operations to the graphic information in the predetermined order to provide graphic information adapted to a set of display characteristics. The method of claim 8, comprising the step of: The method of claim 1, further comprising providing graphical information in a format adapted to a set of display characteristics to a computing device for displaying the graphical information. The method further comprises the step of interpreting the graphic information in a format adapted to the set of display characteristics to provide the graphic information in a format readable by the computing device for display. The method of claim 1, wherein is independent of the type of computing device. The method of claim 1, wherein the scheme can be determined to optimize a speed at which the graphical information is provided to the computing device and a speed at which the computing device displays the graphical information. A system for modifying graphical information to be displayed on a computing device having a set of display characteristics representing a display function of the computing device, the system comprising:
An adaptation mechanism for evaluating a set of display characteristics and a characteristic of the graphic information to determine a method of adapting the characteristics of the graphic information to a set of display characteristics;
A graphic correction mechanism for harmonizing the characteristics of the graphic information with a set of display characteristics according to the method;
A controller for adjusting the modification of the graphic information to provide the graphic information adapted to the set of display characteristics. 14. The graphics acquisition mechanism of claim 13, further comprising: a graphics acquisition mechanism for receiving the request for modification of the graphics information, the request including an indication of a set of display characteristics of the computing device, and obtaining the graphics information in response. System. The system of claim 14, further comprising a request analysis mechanism for obtaining a set of display characteristics from the request. 14. The system of claim 13, further comprising a format conversion mechanism for converting graphic information into a first format. 17. The system of claim 16, further comprising a graphic abstraction mechanism for creating an abstract representation of graphic information, wherein the first format is adapted to facilitate creation of the abstract representation. The adaptation mechanism is:
A characteristic interpreting mechanism for determining a set of graphical display constraints for the computing device based on the set of display characteristics and determining a set of operations to adapt the characteristics of the graphical information to the set of constraints;
A control mechanism for constructing the scheme so as to apply each operation of the set of operations to the abstract representation in a predetermined order, wherein the graphic harmony mechanism comprises:
Applying the method to graphic information by applying each operation of the set of operations to the abstract representation in the predetermined order to provide graphic information in a format adapted to a set of display characteristics. The system of claim 17, including an operating mechanism. The adaptation mechanism is:
A characteristic interpreting mechanism for determining a set of graphical display constraints for the computing device based on the set of display characteristics and determining a set of operations to adapt the characteristics of the graphical information to the set of constraints;
14. The system of claim 13, further comprising a control mechanism for constructing the scheme to apply each operation of the set of operations to the abstract representation in a predetermined order. In order for the graphic harmonization mechanism to provide graphic information in a format adapted to a set of display characteristics, the method is applied to the graphic information in the predetermined order by applying each operation of the set of operations to the graphic information. 20. The system according to claim 19, comprising an operating mechanism for applying to the system. 14. The system of claim 13, further comprising a communication module for providing graphical information harmonized in a form adapted to a set of display characteristics to a computing device for displaying the graphic information. In order for the computing device to provide the graphical information in a format that can be interpreted by the computing device for displaying the graphical information, a graphics interpretation mechanism for interpreting the graphical information in a format adapted to a set of display characteristics is provided. 14. The system of claim 13, further comprising and wherein the format adapted for display is independent of the type of computing device. 14. The system of claim 13, wherein the scheme can be determined to optimize the speed at which graphical information is provided to the computing device and the speed at which the computing device displays graphical information. A computer-readable medium storing computer-executable instructions for modifying graphical information to be displayed on a computing device having a set of display characteristics representing a display function of the computing device, the computer-executable instructions comprising: But,
Determining a method of adapting the characteristics of the graphic information to the set of display characteristics; and providing the characteristics of the graphic information to the set of display characteristics according to the method to provide the graphic information in a format adapted to the set of display characteristics. And a reconciling step. Before the decision step,
Receiving a request for modification of the graphical information, the request comprising an indication of a set of display characteristics of the computing device;
Obtaining the graphical information in response to the request. 26. The computer-executable instructions of claim 25, wherein the method is based on the indication of a set of display characteristics of the request. 26. The computer-executable instructions of claim 24, further comprising the step of converting the graphical information to a first format before reconciling the characteristics of the graphical information. 28. The computer-executable instructions of claim 27, further comprising creating an abstract representation of the graphical information in a first format suitable for facilitating the creation of the abstract representation. 29. The computer-executable instructions of claim 28, wherein determining comprises using the abstract representation to determine a characteristic of the graphical information. The deciding step is
Determining a set of graphical display constraints for the computing device based on the set of display characteristics;
Determining a set of operations that adapts the characteristics of the graphic information to the set of graphic display constraints;
Constructing the scheme to apply each operation of the set of operations to the abstract representation in a predetermined order;
The step of harmonizing
Applying the method to the graphic information by applying each operation of the set of operations to the abstract representation in the predetermined order to provide the graphic information in a format adapted to the set of display characteristics. 30. The computer-executable instructions of claim 29, comprising: The deciding step is
Determining a set of graphical display constraints for the computing device based on the set of display characteristics;
Determining a set of operations that adapts the characteristics of the graphic information to the set of graphic display constraints;
Constructing the scheme so that each operation of the set of operations is applied to the graphic information in a predetermined order. The harmonizing step applies the method to the graphic information by applying each operation of the set of operations to the graphic information in the predetermined order to provide graphic information adapted to a set of display characteristics. 32. The computer-executable instructions of claim 31, comprising the step of: The computer-executable instructions of claim 24, further comprising providing graphical information in a form adapted to a set of display characteristics to a computing device for displaying the graphical information. The method further includes the step of interpreting the graphical information in a format adapted to the set of display characteristics on the computing device to provide the graphical information in a format readable to the computing device for display. 26. The computer-executable instructions of claim 24, wherein the format adapted to is independent of the type of computing device. 26. The computer-executable instructions of claim 24, wherein the scheme can be determined to optimize the speed at which the graphical information is provided to the computing device and the speed at which the computing device displays the graphical information.

Images