최소 단어 이상 선택하여야 합니다.
최대 10 단어까지만 선택 가능합니다.
다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
NTIS 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
DataON 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
Edison 바로가기다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
Kafe 바로가기국가/구분 | United States(US) Patent 등록 |
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국제특허분류(IPC7판) |
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출원번호 | US-0819449 (2001-03-28) |
발명자 / 주소 |
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 | 피인용 횟수 : 52 인용 특허 : 74 |
System and method for constructing a 3D model of an object based on a series of silhouette and texture map images. In the exemplary embodiment an object is placed on a rotating turntable and a camera, which is stationary, captures images of the object as it rotates on the turntable. In one pass, the
System and method for constructing a 3D model of an object based on a series of silhouette and texture map images. In the exemplary embodiment an object is placed on a rotating turntable and a camera, which is stationary, captures images of the object as it rotates on the turntable. In one pass, the system captures a number of photographic images that will be processed into image silhouettes. In a second pass, the system gathers texture data. After a calibration procedure (used to determine the camera's focal length and the turntable's axis of rotation), a silhouette processing module determines a set of two-dimensional polygon shapes (silhouette contour polygons) that describe the contours of the object. The system uses the silhouette contour polygons to create a 3D polygonal mesh model of the object. The system determines the shape of the 3D model analytically-by finding the areas of intersection between the edges of the model faces and the edges of the silhouette contour polygons. The system creates an initial, (rough) model of the 3D object from one of the silhouette contour polygons, then executes an overlaying procedure to process each of the remaining silhouette contour polygons. In the overlaying process, the system processes the silhouette contour polygons collected from each silhouette image, projecting each face of the (rough) 3D model onto the image plane of the silhouette contour polygons. The overlaying of each face of the (rough) 3D model onto the 2D plane of the silhouette contour polygons enables the present invention to determine those areas that are extraneous and should be removed from the (rough) 3D model. As the system processes the silhouette contour polygons in each image it removes the extraneous spaces from the initial object model and creates new faces to patch "holes." The polygonal mesh model, once completed, can be transformed into a triangulated mesh model. In a subsequent step, the system uses a deterministic procedure to map texture from the texture images onto the triangles of the 3D mesh model, locating that area in the various texture map images that is "best" for each mesh triangle.
What is claimed is: 1. A method for constructing a 3D model of an object comprising the steps of: a. capturing a series of photographic images of an object using a camera having a planar image collector, where the step of capturing images collects the images of the object from a plurality of differ
What is claimed is: 1. A method for constructing a 3D model of an object comprising the steps of: a. capturing a series of photographic images of an object using a camera having a planar image collector, where the step of capturing images collects the images of the object from a plurality of different angles, where the angle associated with each image is determined from a pre-selected reference point in three-dimensional space and where from that associated angle it is possible to determine the location in three-dimensional space of the plane of the image collection; b. processing each photographic image to identify clusters of pixels in the image that describe the object; c. tracing the perimeter of each cluster of the pixels in the image that describe the object to gather a set of pixels which describe a silhouette contour of the object's shape, and thereby create a set of silhouette contours; d. processing the points of the silhouette contours to select from those points the vertices of a polygon which approximates the silhouette contour of the object's shape, and thereby create a set of silhouette contour polygons; e. creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the three-dimensional model being formed by making a conical projection from one of the set of silhouette contour polygons, creating along the bounds of the conical projection a near and far face for the object model, with the near and far faces each representing a projection of the vertices of the silhouette contour polygon in three-dimensional space, and creating additional faces to span volume between the points of the near and far faces based on pairs of adjacent vertices in the near and far faces; and f. refining the initial three-dimensional model of the object by selecting the silhouette contour polygons for a given image, projecting each face of the initial three-dimensional model of the object onto the two-dimensional plane of image collection for the given image and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the silhouette contour polygons for the given image and creating a set of three dimensional coordinates for each of the vertices of the revised set of vertices. 2. A method for constructing a 3D model of an object from a series of photographic images of the object, where the series of photographic images have been captured from a plurality of different angles, where the angle associated with each image is determined from a pre-selected reference point in three-dimensional space and where the image is comprised of a plurality of pixels, the method comprising the steps of: a. processing each photographic image to identify clusters of pixels in the image that describe the object; b. tracing the perimeter of each cluster of the pixels in the image that describe the object to gather a set of pixels which describe a silhouette contour of the object's shape, and thereby create a set of silhouette contours; c. processing the points of the silhouette contours to select from those points the vertices of a polygon which approximates the silhouette contour of the object's shape, and thereby create a set of silhouette contour polygons; d. creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the three-dimensional model being formed by making a conical projection from one of the set of silhouette contour polygons, creating along the bounds of the conical projection a near and far face for the object model, with the near and far faces each representing a projection of the vertices of the silhouette contour polygon in three-dimensional space, and creating additional faces to span volume between the points of the near and far faces based on pairs of adjacent vertices in the near and far faces; and e. refining the initial three-dimensional model of the object by selecting the silhouette contour polygons for a given image, projecting each face of the initial three-dimensional model of the object onto the two-dimensional plane of image collection for the given image and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the silhouette contour polygons for the given image and creating a set of three dimensional coordinates for each of the vertices of the revised set of vertices. 3. A method for constructing a 3D model of an object from a series of photographic images of the object, where the series of photographic images have been captured from a plurality of different angles about the object, where the angle associated with each image is determined from a pre-selected reference point in three-dimensional space and where the image is comprised of a plurality of pixels, the method comprising the steps of: a. processing each photographic image to identify those clusters of pixels in the image that describe the object; b. processing those clusters of pixels which describe the object and select from those points the vertices of a polygon which approximates a silhouette contour describing the object's shape, and thereby creating a set of silhouette contour polygons; c. creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; and d. refining the initial three-dimensional model of the object by selecting the silhouette contour polygons for a given image, projecting each face of the initial three-dimensional model of the object onto the two-dimensional plane of image collection for the given image and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the silhouette contour polygons for the given image and creating a set of three dimensional coordinates for each of the vertices of the revised set of vertices. 4. A method for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the method comprising the steps of: a. processing the plurality of contours which describe the object and selecting from the points of each contour the vertices of a polygon which approximates a contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; and c. refining the initial three-dimensional model of the object by projecting each face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of one of the two-dimensional silhouette contour polygons and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the projected silhouette contour polygon. 5. A method for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the method comprising the steps of: a. processing the plurality of contours which describe the object and selecting from the pixels of each contour the vertices of a polygon which approximates that contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; c. projecting a face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of at least one of the silhouette contour polygons that has not been used to create the initial three-dimensional model; d. locating amongst the edges formed by the vertices of one of the projected faces an edge that intersects one of the edges of the at least one of the silhouette contour polygons; e. determining a three-dimensional coordinate for the point of intersection based on the three-dimensional coordinates of the projected edge from the face that was intersected; f. placing a reference to the three-dimensional coordinates for the point of intersection onto a revised list of coordinates for the face; g. following from the point of intersection the vertices of the projected face until reaching a second point of intersection, this step of following the vertices including the step of placing on the revised list of coordinates for the face a reference to the three-dimensional point which corresponds to each projected vertex of the face; h. determining a three-dimensional coordinate for the second point of intersection based on the three-dimensional coordinates of the projected edge from the face that was intersected; i. placing a reference to the three-dimensional coordinates for the second point of intersection onto a revised list of coordinates for the face; and j. following from the second point of intersection the vertices of the projected silhouette contour polygon until reaching a third point of intersection, this step of following the vertices of the silhouette contour polygon including the step of generating a three-dimensional coordinate for each vertex of the silhouette contour polygon encountered and placing a reference to each such coordinate on the revised list of coordinates for the face. 6. A method for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the method comprising the steps of: a. processing the plurality of contours which describe the object and selecting from the points of each contour the vertices of a polygon which approximates a contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; c. projecting a face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of at least one of the silhouette contour polygons that has not been used to create the initial three-dimensional model; d. locating amongst the edges formed by the vertices of one of the projected faces an edge that intersects one of the edges of the at least one of the silhouette contour polygons; e. commencing a tour from the point of intersection by following from the point of intersection the vertices of the projected face which lie inside the bounds of the intersected silhouette contour polygon until reaching a second point of intersection between an edge of the projected face and the at least one of the silhouette contour polygons; f. following from the second point of intersection the vertices of the projected silhouette contour polygon until reaching a third point of intersection between an edge of the silhouette contour polygon and an edge of the projected face; and g. storing on a revised list of vertices for the projected face a list of three-dimensional coordinates that correspond to each of the points visited on the tour of vertices. 7. A method for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the method comprising the steps of: a. processing the plurality of contours which describe the object and selecting from the points of each contour the vertices of a polygon which approximates a contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; c. projecting a face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of at least one of the silhouette contour polygons that has not been used to create the initial three-dimensional model; d. following those vertices of the projected face that lie within the boundary of the projected silhouette contour polygon until reaching a point of intersection, this step of following the vertices of the projected face including the step of placing on a revised list of coordinates for the face a reference to the three-dimensional point which corresponds to each projected vertex of the face; e. determining a three-dimensional coordinate for the point of intersection based on the three-dimensional coordinates of the projected edge from the face that was intersected; f. placing a reference to the three-dimensional coordinates for the point of intersection onto a revised list of coordinates for the face; g. placing a reference to the three-dimensional coordinate for the point of intersection onto a point pair list that is associated with the edge of the silhouette contour polygon that is intersected; h. obtaining that end point of the intersected edge of the silhouette contour polygon which lies inside of the bounds of the intersected face; i. determining a three-dimensional coordinate for the end point of the silhouette contour polygon based on the three-dimensional coordinates of the face that was intersected; j. placing a reference to the three-dimensional coordinates for the end point of the silhouette contour polygon onto a revised list of coordinates for the face; k. placing a reference to the three-dimensional coordinate for the end point of the silhouette contour polygon onto a point pair list that is associated with the edge of the silhouette contour polygon that is intersected; and l. creating a new face for the 3D model of the object using the points referenced in the point pair list. 8. A method for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the method comprising the steps of: a. processing the plurality of contours which describe the object and selecting from the points of each contour the vertices of a polygon which approximates a contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; c. projecting a face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of at least one of the silhouette contour polygons that has not been used to create the initial three-dimensional model; d. locating amongst the edges formed by the vertices of one of the projected faces an edge that intersects one of the edges of the projected silhouette contour; e. commencing a tour that follows from the point of intersection the vertices of the projected silhouette contour polygon until reaching a second point of intersection between an edge of the silhouette contour polygon and an edge of the projected face; f. storing on a revised list of vertices for the projected face a list of three-dimensional coordinates that correspond to each of the points visited on the tour of vertices; g. storing on a list associated with each edge of the silhouette contour polygon being toured a reference to the three-dimensional coordinate for the beginning and ending points of each portion of each edge of the silhouette contour polygon that is visited on the tour of vertices; and h. creating a new face for the 3D model of the object using the points referenced in the point pair list. 9. A method for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the method comprising the steps of: a. processing the plurality of contours which describe the object and select from the points of each contour the vertices of a polygon which approximates a contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; c. refining the initial three-dimensional model of the object by projecting each face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of one of the two-dimensional silhouette contour polygons and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the projected silhouette contour polygon; and d. creating a triangulated mesh model from the refined three-dimensional model of the object. 10. A method for constructing a 3D model of an object from a series of photographic images of the object, where the series of photographic images have been captured from a plurality of different angles, where the angle associated with each image is determined from a pre-selected reference point in three-dimensional space and where the image is comprised of a plurality of pixels, the method comprising the steps of: a. processing each photographic image to identify those clusters of pixels in the image that describe the object; b. tracing the perimeter of each cluster of the pixels in the image that describe the object to gather a set of pixels which describe a silhouette contour of the object's shape, and thereby create a set of silhouette contours; c. processing the points of the silhouette contours to select from those points the vertices of a polygon which approximates the silhouette contour of the object's shape, and thereby create a set of silhouette contour polygons; d. creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the three-dimensional model being formed by making a conical projection from one of the set of silhouette contour polygons, creating along the bounds of the conical projection a near and far face for the object model, with the near and far faces each representing a projection of the vertices of the silhouette contour polygon in three-dimensional space, and creating additional faces to span volume between the points of the near and far faces based on pairs of adjacent vertices in the near and far faces; and e. refining the initial three-dimensional model of the object by selecting the silhouette contour polygons for a given image, projecting each face of the initial three-dimensional model of the object onto the two-dimensional plane of image collection for the given image and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the silhouette contour polygons for the given image and creating a set of three dimensional coordinates for each of the vertices of the revised set of vertices. 11. A method for constructing a 3D model of an object from a series of photographic images of the object, where the series of photographic images have been captured from a plurality of different angles, where the angle associated with each image is determined from a pre-selected reference point in three-dimensional space and where the image is comprised of a plurality of pixels, the method comprising the steps of: a. capturing a first plurality of images of the object under lighting conditions in which the image is backlit such that the background is lit and the object is not lit; b. capturing a second plurality of images under lighting conditions in which the image is front lit; and c. processing the first plurality of images to locate within each image a set of vertices which describe the contours of the object and constructing from those vertices a three dimensional model of the object, the three dimensional model being comprised of a set of polygonal faces; d. processing each face of the polygon to locate in each of the second plurality of images that portion of the image which corresponds to the face of the model; e. determining a value for the area of that portion of each image of the second plurality of images which corresponds to the face of the model; and f. associating with the face the one image from the second plurality of images which has the largest area value. 12. A system for constructing a 3D model of an object the system comprising: a. an image capturing module for capturing a series of photographic images of an object using a camera having a planar image collector, where the step of capturing images collects the images of the object from a plurality of different angles, where the angle associated with each image is determined from a pre-selected reference point in three-dimensional space and where from that associated angle it is possible to determine the location in three-dimensional space of the plane of the image collection; b. a cluster identification module for processing each photographic image to identify clusters of pixels in the image that describe the object; c. a silhouette contour tracing module for tracing the perimeter of each cluster of the pixels in the image that describe the object to gather a set of pixels which describe a silhouette contour of the object's shape, and thereby create a set of silhouette contours; d. a polygon shape determination module for processing the points of the silhouette contours to select from those points the vertices of a polygon which approximates the silhouette contour of the object's shape, and thereby create a set of silhouette contour polygons; e. an initial 3D model building module for creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the three-dimensional model being formed by making a conical projection from one of the set of silhouette contour polygons, creating along the bounds of the conical projection a near and far face for the object model, with the near and far faces each representing a projection of the vertices of the silhouette contour polygon in three-dimensional space, and creating additional faces to span volume between the points of the near and far faces based on pairs of adjacent vertices in the near and far faces; and f. a refining module for refining the initial three-dimensional model of the object by selecting the silhouette contour polygons for a given image, projecting each face of the initial three-dimensional model of the object onto the two-dimensional plane of image collection for the given image and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the silhouette contour polygons for the given image and creating a set of three dimensional coordinates for each of the vertices of the revised set of vertices. 13. A computer-based system for constructing a 3D model of an object from a series of photographic images of the object, where the series of photographic images have been captured from a plurality of different angles, where the angle associated with each image is determined from a pre-selected reference point in three-dimensional space and where the image is comprised of a plurality of pixels, the system comprising: a. a computer module for processing each photographic image to identify clusters of pixels in the image that describe the object; b. a computer module for tracing the perimeter of each cluster of the pixels in the image that describe the object to gather a set of pixels which describe a silhouette contour of the object's shape, and thereby create a set of silhouette contours; c. a computer module for processing the points of the silhouette contours to select from those points the vertices of a polygon which approximates the silhouette contour of the object's shape, and thereby create a set of silhouette contour polygons; d. a computer module for creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the three-dimensional model being formed by making a conical projection from one of the set of silhouette contour polygons, creating along the bounds of the conical projection a near and far face for the object model, with the near and far faces each representing a projection of the vertices of the silhouette contour polygon in three-dimensional space, and creating additional faces to span volume between the points of the near and far faces based on pairs of adjacent vertices in the near and far faces; and e. a computer module for refining the initial three-dimensional model of the object by selecting the silhouette contour polygons for a given image, projecting each face of the initial three-dimensional model of the object onto the two-dimensional plane of image collection for the given image and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the silhouette contour polygons for the given image and creating a set of three dimensional coordinates for each of the vertices of the revised set of vertices. 14. A system for constructing a 3D model of an object from a series of photographic images of the object, where the series of photographic images have been captured from a plurality of different angles about the object, where the angle associated with each image is determined from a pre-selected reference point in three-dimensional space and where the image is comprised of a plurality of pixels, the system comprising: a. a cluster identification module for processing each photographic image to identify those clusters of pixels in the image that describe the object; b. a polygon shape determination module for processing those clusters of pixels which describe the object and select from those points the vertices of a polygon which approximates a silhouette contour describing the object's shape, and thereby creating a set of silhouette contour polygons; c. an initial model generating module for creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; and d. a refining module for refining the initial three-dimensional model of the object by selecting the silhouette contour polygons for a given image, projecting each face of the initial three-dimensional model of the object onto the two-dimensional plane of image collection for the given image and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the silhouette contour polygons for the given image and creating a set of three dimensional coordinates for each of the vertices of the revised set of vertices. 15. A computer-based system for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the system comprising: a. a computer module for processing the plurality of contours which describe the object and selecting from the points of each contour the vertices of a polygon which approximates a contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. a computer module for creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; and c. a computer module for refining the initial three-dimensional model of the object by projecting each face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of one of the two-dimensional silhouette contour polygons and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the projected silhouette contour polygon. 16. A computer-based system for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the system comprising: a. a computer software component for processing the plurality of contours which describe the object and selecting from the pixels of each contour the vertices of a polygon which approximates that contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. a computer software for creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; c. a computer software component for projecting a face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of at least one of the silhouette contour polygons that has not been used to create the initial three-dimensional model; d. a computer software component for locating amongst the edges formed by the vertices of one of the projected faces an edge that intersects one of the edges of the at least one of the silhouette contour polygons; e. a computer software component for determining a three-dimensional coordinate for the point of intersection based on the three-dimensional coordinates of the projected edge from the face that was intersected; f. a computer software component for placing a reference to the three-dimensional coordinates for the point of intersection onto a revised list of coordinates for the face; g. a computer software component for following from the point of intersection the vertices of the projected face until reaching a second point of intersection, this step of following the vertices including the step of placing on the revised list of coordinates for the face a reference to the three-dimensional point which corresponds to each projected vertex of the face; h. a computer software component for determining a three-dimensional coordinate for the second point of intersection based on the three-dimensional coordinates of the projected edge from the face that was intersected; i. a computer software component for placing a reference to the three-dimensional coordinates for the second point of intersection onto a revised list of coordinates for the face; and j. a computer software component for following from the second point of intersection the vertices of the projected silhouette contour polygon until reaching a third point of intersection, this step of following the vertices of the silhouette contour polygon including the step of generating a three-dimensional coordinate for each vertex of the silhouette contour polygon encountered and placing a reference to each such coordinate on the revised list of coordinates for the face. 17. A computer-based system for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the system comprising: a. a silhouette contour extraction module for processing the plurality of contours which describe the object and selecting from the points of each contour the vertices of a polygon which approximates a contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. an initial three-dimensional model building module for creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; c. a refining module comprised for projecting a face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of at least one of the silhouette contour polygons that has not been used to create the initial three-dimensional model; d. the refining module further comprised for locating amongst the edges formed by the vertices of one of the projected faces an edge that intersects one of the edges of the at least one of the silhouette contour polygons; e. the refining module further comprised for commencing a tour from the point of intersection by following from the point of intersection the vertices of the projected face which lie inside the bounds of the intersected silhouette contour polygon until reaching a second point of intersection between an edge of the projected face and the at least one of the silhouette contour polygons; f. the refining module further comprised for following from the second point of intersection the vertices of the projected silhouette contour polygon until reaching a third point of intersection between an edge of the silhouette contour polygon and an edge of the projected face; and g. the refining module further comprised for storing on a revised list of vertices for the projected face a list of three-dimensional coordinates that correspond to each of the points visited on the tour of vertices. 18. A computer-based system for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the system comprising: a. a computer software component for processing the plurality of contours which describe the object and selecting from the points of each contour the vertices of a polygon which approximates a contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. a computer software component for creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; c. a computer software component for projecting a face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of at least one of the silhouette contour polygons that has not been used to create the initial three-dimensional model; d. a computer software component for following those vertices of the projected face that lie within the boundary of the projected silhouette contour polygon until reaching a point of intersection, this step of following the vertices of the projected face including the step of placing on a revised list of coordinates for the face a reference to the three-dimensional point which corresponds to each projected vertex of the face; e. a computer software component for determining a three-dimensional coordinate for the point of intersection based on the three-dimensional coordinates of the projected edge from the face that was intersected; f. a computer software component for placing a reference to the three-dimensional coordinates for the point of intersection onto a revised list of coordinates for the face; g. a computer software component for placing a reference to the three-dimensional coordinate for the point of intersection onto a point pair list that is associated with the edge of the silhouette contour polygon that is intersected; h. a computer software component for obtaining that end point of the intersected edge of the silhouette contour polygon which lies inside of the bounds of the intersected face; i. a computer software component for determining a three-dimensional coordinate for the end point of the silhouette contour polygon based on the three-dimensional coordinates of the face that was intersected; j. a computer software component for placing a reference to the three-dimensional coordinates for the end point of the silhouette contour polygon onto a revised list of coordinates for the face; k. a computer software component for placing a reference to the three-dimensional coordinate for the end point of the silhouette contour polygon onto a point pair list that is associated with the edge of the silhouette contour polygon that is intersected; and l. a computer software component for creating a new face for the 3D model of the object using the points referenced in the point pair list. 19. A computer system for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the system comprising: a. a computer module for processing the plurality of contours which describe the object and selecting from the points of each contour the vertices of a polygon which approximates a contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. a computer module for creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; c. a computer module for projecting a face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of at least one of the silhouette contour polygons that has not been used to create the initial three-dimensional model; d. a computer module for locating amongst the edges formed by the vertices of one of the projected faces an edge that intersects one of the edges of the projected silhouette contour; e. a computer module for commencing a tour that follows from the point of intersection the vertices of the projected silhouette contour polygon until reaching a second point of intersection between an edge of the silhouette contour polygon and an edge of the projected face; f. a computer module for storing on a revised list of vertices for the projected face a list of three-dimensional coordinates that correspond to each of the points visited on the tour of vertices; g. a computer module for storing on a list associated with each edge of the silhouette contour polygon being toured a reference to the three-dimensional coordinate for the beginning and ending points of each portion of each edge of the silhouette contour polygon that is visited on the tour of vertices; and h. a computer module for creating a new face for the 3D model of the object using the points referenced in the point pair list. 20. A computer-based system for constructing a 3D model of an object from a plurality of two-dimensional contours comprised of pixels that describe the boundaries of the object, with each of the plurality of two-dimensional contours representing a view of the object from a different angle, where the angle associated with each contour being determined from a pre-selected reference point in three-dimensional space, the system comprising: a. a computer module for processing the plurality of contours which describe the object and select from the points of each contour the vertices of a polygon which approximates a contour describing the object's shape, and thereby creating a set of silhouette contour polygons; b. a computer module for creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the initial three-dimensional model of the object being comprised of a plurality of polygonal faces; c. a computer module for refining the initial three-dimensional model of the object by projecting each face of the initial three-dimensional model of the object onto a two-dimensional plane which also contains a projection of one of the two-dimensional silhouette contour polygons and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the projected silhouette contour polygon; and d. a computer module for creating a triangulated mesh model from the refined three-dimensional model of the object. 21. A system for constructing a 3D model of an object from a series of photographic images of the object, where the series of photographic images have been captured from a plurality of different angles, where the angle associated with each image is determined from a pre-selected reference point in three-dimensional space and where the image is comprised of a plurality of pixels, the system comprising: a. means for processing each photographic image to identify those clusters of pixels in the image that describe the object; b. means for tracing the perimeter of each cluster of the pixels in the image that describe the object to gather a set of pixels which describe a silhouette contour of the object's shape, and thereby create a set of silhouette contours; c. means for processing the points of the silhouette contours to select from those points the vertices of a polygon which approximates the silhouette contour of the object's shape, and thereby create a set of silhouette contour polygons; d. means for creating an initial three-dimensional model of the object using one of the silhouette contour polygons, the three-dimensional model being formed by making a conical projection from one of the set of silhouette contour polygons, creating along the bounds of the conical projection a near and far face for the object model, with the near and far faces each representing a projection of the vertices of the silhouette contour polygon in three-dimensional space, and creating additional faces to span volume between the points of the near and far faces based on pairs of adjacent vertices in the near and far faces; and e. means for refining the initial three-dimensional model of the object by selecting the silhouette contour polygons for a given image, projecting each face of the initial three-dimensional model of the object onto the two-dimensional plane of image collection for the given image and revising the set of vertices of the projected face so that it bounds the space which falls within the boundaries of the silhouette contour polygons for the given image and creating a set of three dimensional coordinates for each of the vertices of the revised set of vertices. 22. A computer-based system for constructing a 3D model of an object from a series of photographic images of the object, where the series of photographic images have been captured from a plurality of different angles, where the angle associated with each image is determined from a pre-selected reference point in three-dimensional space and where the image is comprised of a plurality of pixels, the system comprising: a. an image capturing module for capturing a first plurality of images of the object under lighting conditions in which the image is backlit such that the background is lit and the object is not lit; b. the image capturing module further comprised for capturing a second plurality of images under lighting conditions in which the image is front lit; and c. a texture map module for processing the first plurality of images to locate within each image a set of vertices which describe the contours of the object and constructing from those vertices a three dimensional model of the object, the three dimensional model being comprised of a set of polygonal faces; d. the texture map module further comprised to process each face of the polygon to locate in each of the second plurality of images that portion of the image which corresponds to the face of the model; e. the texture map module further comprised to determine a value for the area of that portion of each image of the second plurality of images which corresponds to the face of the model; and f. the texture map module further comprised to associate with the face the one image from the second plurality of images which has the largest area value.
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