초록 ▼

A method for processing a three-dimensional (3D) graphic object, having the first step of converting a set of vertices for the 3D graphics object. Further, decomposing the 3D graphics object into a set of segments; and for each segment: (1) extracting a set of vertex coordinates; and (2) subtracting

A method for processing a three-dimensional (3D) graphic object, having the first step of converting a set of vertices for the 3D graphics object. Further, decomposing the 3D graphics object into a set of segments; and for each segment: (1) extracting a set of vertex coordinates; and (2) subtracting the set of vertex coordinates from a previously determined set of vertex coordinates to produce a set of encoded vertex coordinates. Then, compressing the set of encoded vertex coordinates. An apparatus for performing the method.

대표청구항 ▼

1. A method comprising:decomposing a 3D graphics object into a set of segments, where each segment has a plurality of faces, each face having a normal vector, wherein there is a point in space, for each segment, at which a plurality of normal vectors of that segment converge;for each segment, extrac

1. A method comprising:decomposing a 3D graphics object into a set of segments, where each segment has a plurality of faces, each face having a normal vector, wherein there is a point in space, for each segment, at which a plurality of normal vectors of that segment converge;for each segment, extracting a set of vertex coordinates from a previously determined set of vertex coordinates to produce a set of encoded vertex coordinates; andfor each segment, compressing a plurality of said set of encoded vertex coordinates. 2. The method of claim 1 further comprising, prior to decomposing the graphics object, converting a set of vertices for the graphics object from a floating-point to an integer representation. 3. The method of claim 1 wherein the compression uses a lossless compression scheme. 4. The method of claim 2 wherein the extraction for each segment includes sweeping a surface of the segment in longitudinal slices. 5. The method of claim 3 wherein the compression scheme is Huffman coding. 6. The method of claim 1 wherein the graphics object is one of a cylinder, a sphere, and a cone, and the segments are cylindrical. 7. An apparatus comprising:means for decomposing a 3D graphics object into a set of segments each having a plurality of faces, each face having a normal vector, wherein each segment has a convergence point in space at which a plurality of normal vectors of the segment converge;means for translating the convergence point of each segment to an origin of a 3D coordinate system;means for rotating each segment so that a surface point of the segment is on an axis of the coordinate system and an integral along the longitude at the equatorial plane produces a highest value for all possible rotations;means for extracting a set of vertex coordinates from each segment;means for subtracting the extracted set of vertex coordinates from a previously determined set of vertex coordinates of that segment to produce a set of encoded vertex coordinates for that segment; andmeans for compressing a plurality of said set of encoded vertex coordinates for each segment. 8. The apparatus of claim 7 further comprising means for converting a set of vertices of each segment from a floating point to an integer representation. 9. The apparatus of claim 7 wherein the extraction means includes means for sweeping a surface of each segment in longitudinal slices. 10. The apparatus of claim 8 wherein the integer representation is 64 bits. 11. An article of manufacture comprising:a machine readable medium having code stored thereon that, when executed by a processor, causes a system to slice a 3D graphics object into a set of segments such that for each segment there is a point P in space from which a complete surface of that segment can be seen, and for each segment, sweep a surface of the segment until a vertex in a 3D vertex pool of the graphics object is encountered, record a position of the encountered vertex in relation to a recorded position of a previously encountered vertex, and apply a compression scheme to the recorded positions. 12. The article of manufacture of claim 11 wherein the machine readable medium has code that causes vertices of the graphics object to be converted from a floating-point to integer representation. 13. The article of manufacture of claim 11 wherein the machine readable medium has code that causes the surface of each segment to be swept in longitudinal slices. 14. The article of manufacture of claim 11 wherein the machine readable medium has code that causes the system to determine a plurality of 3D graphics objects depicted in a 3D image and store coordinate information as to the location of the plurality of objects so that the objects may be placed in their original positions during reconstruction of the image, and wherein the machine readable medium has further code that causes the system to perform the slicing, sweeping, recording and compression operations on each of the plurality of objects separately. 1 5. The article of manufacture of claim 11 wherein the machine readable medium has code that causes the system to translate each segment such that the point P of each segment is located at the origin of a 3D coordinate space, prior to sweeping the surface of the segment. 16. The article of manufacture of claim 15 wherein the machine readable medium has code that causes the system to rotate each segment until a surface point of the segment is on an axis of the coordinate system and an integral along the longitude at the equatorial plane produces a highest value for all possible rotations. 17. An apparatus comprising:a predictor to determine the shape of a 3D image and based on the determined shape operate in a selected 3D coordinate system; andan encoder/compressor, to decompose the image into a set of segments, each segment having a plurality of faces, each face having a normal vector, wherein each segment has a convergence point in space at which a plurality of normal vectors converge, the encoder/compressor to treat each segment separately for purposes of data compression, translate the convergence point of each segment to an origin of the selected 3D coordinate system, rotate each segment so that a surface point of the segment is on an axis of the coordinate system and an integral along a longitude at the equatorial plane produces a highest value for all possible rotations, the encoder/compressor to extract a vertex from each segment, subtract the vertex from a previously determined vertex of that segment to produce an encoded vertex for that segment, the encoder/compressor to compress a plurality of said encoded vertices of each segment. 18. The apparatus of claim 17 wherein the predictor is to convert a 3D vertex pool of the image from floating point into integer representation for use by the encoder/compressor. 19. The apparatus of claim 17 wherein the predictor and the encoder/compressor are implemented by a programmed processor, the apparatus further comprising a bus to which the programmed processor is coupled, and a communication interface device coupled to the bus to receive the compressed plurality of encoded vertices of each segment. 20. The apparatus of claim 19 wherein the communication interface device is one of a network card and a modem interface for accessing a network.