초록 ▼

A device for determining the surface topology and associated color of a structure, such as a teeth segment, includes a scanner for providing depth data for points along a two-dimensional array substantially orthogonal to the depth direction, and an image acquisition means for providing color data fo

A device for determining the surface topology and associated color of a structure, such as a teeth segment, includes a scanner for providing depth data for points along a two-dimensional array substantially orthogonal to the depth direction, and an image acquisition means for providing color data for each of the points of the array, while the spatial disposition of the device with respect to the structure is maintained substantially unchanged. A processor combines the color data and depth data for each point in the array, thereby providing a three-dimensional color virtual model of the surface of the structure. A corresponding method for determining the surface topology and associated color of a structure is also provided.

대표청구항 ▼

The invention claimed is: 1. Device for determining the surface topology and associated color of at least a portion of a three dimensional structure, comprising: (a) scanning means adapted for providing depth data of said portion corresponding to a two-dimensional reference array substantially orth

The invention claimed is: 1. Device for determining the surface topology and associated color of at least a portion of a three dimensional structure, comprising: (a) scanning means adapted for providing depth data of said portion corresponding to a two-dimensional reference array substantially orthogonal to a depth direction; (b) imaging means adapted for providing two-dimensional color image data of said portion associated with said reference array; wherein the device is adapted for maintaining a spatial disposition with respect to said portion that is substantially fixed during operation of said scanning means and said imaging means. 2. Device according to claim 1, wherein said device is adapted for providing a time interval between acquisition of said depth data and acquisition of said color image data such that substantially no significant relative movement between said device and said portion occurs. 3. Device according to claim 2, wherein said time interval is between about 0 seconds to about 100 milliseconds, preferably between 0 and 50 milliseconds, and more preferably between 0 and 20 milliseconds. 4. Device according to claim 1, further comprising processing means for associating said color data with said depth data for corresponding data points of said reference array. 5. Device according to claim 1, wherein said operation of said scanning means is based on confocal imaging techniques. 6. Device according to claim 5, wherein said scanning means comprises: a probing member with a sensing face; first illumination means for providing a first array of incident light beams transmitted towards the structure along an optical path through said probing unit to generate illuminated spots on said portion along said depth direction, wherein said first array is defined within said reference array; a light focusing optics defining one or more focal planes forward said probing face at a position changeable by said optics, each light beam having its focus on one of said one or more focal plane; a translation mechanism for displacing said focal plane relative to the structure along an axis defined by the propagation of the incident light beams; a first detector having an array of sensing elements for measuring intensity of each of a plurality of light beams returning from said spots propagating through an optical path opposite to that of the incident light beams; a processor coupled to said detector for determining for each light beam a spot-specific position, being the position of the respective focal plane of said one or more focal planes yielding maximum measured intensity of the returned light beam, and based on the determined spot-specific positions, generating data representative of the topology of said portion. 7. Device according to claim 6, wherein said first array is arranged to provide depth data at a plurality of predetermined spatial coordinates substantially corresponding to the spatial disposition of said incident light beams. 8. Device according to claim 7, wherein operation of said imaging means is based on: illuminating said portion with three differently-colored illumination radiations, the said illuminations being combinable to provide white light, capturing a monochromatic image of said portion corresponding to each said illuminating radiation, and combining the monochromatic images to create a full color image, wherein each said illuminating radiation is provided in the form of a second array of incident light beams transmitted towards the portion along an optical path through said probing unit to generate illuminated spots on said portion along said depth direction, wherein said second array is defined within said reference frame. 9. Device according to claim 8, wherein said second array is arranged to provide color data at a plurality of spatial coordinates substantially corresponding to the spatial coordinates of said first array. 10. Device according to claim 9, comprising color illumination means adapted for providing three second illuminating radiations, each of a different color. 11. Device according to claim 10, wherein said color illumination means comprises any one of the following: second illumination means for providing said three second illuminating radiations, each of a different color; second illumination means for providing two said second illuminating radiations, and wherein said first illumination means provides another said second illuminating radiation each said second illuminating radiation being of a different color. 12. Device according to claim 11, wherein said second illumination means comprise radiation transmission elements that are configured to be located out of the path of said light beams or said returned light beam at least within said light focusing optics. 13. Device according to claim 12, wherein said probing member is made from a light transmissive material having an upstream optical interface with said light focusing optics and a reflective face for reflecting light between said optical interface and said sensing face. 14. Device according to claim 13, wherein said second illumination means are optically coupled to said optical interface for selectively transmitting illuminating radiations in at least two colors to said portion via said sensing face. 15. Device according to claim 13, wherein said color illumination means comprises second illumination means for providing two said second illuminating radiations, and wherein said first illumination means provides another said second illuminating radiation each said second illuminating radiation being of a different color. 16. Device according to claim 15, wherein said probing member comprises a removable sheath having an inner surface substantially complementary to an outer surface of said probing member, and having a window in registry with said sensing face, wherein said sheath is made from a waveguiding material and is adapted to transmit said light from said second illuminating means from an upstream face thereof to a downstream face associated with said window. 17. Device according to claim 16, wherein said second illumination means are optically coupled to said upstream face for selectively transmitting said second illuminating radiations in at least two colors to said portion via said downstream face. 18. Device according to claim 13, wherein said reflective face comprises a dichroic coating, having relatively high reflectivity and low optical transmission properties for a said second illuminating radiation provided by said first illumination means, and relatively low reflectivity and high optical transmission properties for the two said second illuminating radiations provided by said second illumination means. 19. Device according to claim 12, wherein said second illumination means are adapted for providing second illuminating radiations within said light focusing optics. 20. Device according to claim 19, wherein said second illumination means are adapted for providing second illuminating radiations at an aperture stop plane of said light focusing optics. 21. Device according to claim 19, comprising a mirror inclined to the optical axis of said light focusing optics and having an aperture configured to allow said light beams and said returning light beams to pass therethrough without being optically affected by said mirror, and wherein said second illumination means comprises at least one white illumination source optically coupled with suitable color filters, said filters selectively providing illumination radiation in each color in cooperation with said white illumination source, wherein said mirror is coupled to said white illumination source to direct radiation therefrom along said optical axis. 22. Device according to claim 19, further comprising: a first polarizing element located just downstream of said illumination means so as to polarize the light emitted therefrom; a second polarizing element located just upstream of said first detector, wherein said second polarizing element is crossed with respect to the first polarizing element; and a quarter waveplate at the downstream end of said device. 23. Device according to claim 19, wherein said illumination means are adapted for selective movement in the depth direction. 24. Device according to claim 12, wherein said second illumination means are in the form of any one of the following:— suitable LED's, comprising at least one LED for providing illumination radiation in each color; suitable LED's comprising at least one white illumination source optically coupled with suitable color filters, said filters selectively providing illumination radiation in each color in cooperation with said white illumination source. 25. Device according to claim 8, wherein said first detector is adapted for selectively measuring intensity of each said second illuminating radiation after reflection from said portion. 26. Device according to claim 7, wherein operation of said imaging means is based on any one of the following:— illuminating said portion with substantially white illumination radiation, and capturing a color image of said portion, wherein said white illuminating radiation is provided in the form of a second array of incident light beams transmitted towards the portion along an optical path through said probing unit to generate illuminated spots on said portion along said depth direction, wherein said second array is defined within said reference frame; illuminating said portion with substantially white illumination radiation, selectively passing radiation reflected from said portion through a number of color filters, capturing a monochromatic image of said portion corresponding to each said filter, and combining the monochromatic images to create a full color image, wherein said illuminating radiation is provided in the form of a second array of incident light beams transmitted towards the portion along an optical path through said probing unit to generate illuminated spots on said portion along said depth direction, wherein Said second array is defined within said reference frame; illuminating said portion with three differently-colored illumination radiations, capturing a monochromatic image of said portion corresponding to each said illuminating radiation, and combining the monochromatic images to create a full color image, wherein each said illuminating radiation is provided in the form of a second array of incident light beams transmitted towards the portion along an optical path through said probing unit to generate illuminated spots on said portion along said depth direction, wherein said second array is defined within said reference frame, and wherein said illuminating radiations are provided by said first illumination source. 27. Device according to claim 26, wherein said second array is arranged to provide color data at a plurality of spatial coordinates substantially corresponding to the spatial coordinates of said first array. 28. Device according to claim 27, wherein said imaging means comprises:— white illumination radiation means; second detector having an array of sensing elements for measuring intensity of said white illuminating radiation after reflection from said portion. 29. Device according to claim 10, further comprising a tri-color sequence generator for controlling the illumination of said portion with said second illuminating radiations. 30. Device according to claim 29, further comprising at least one of a tri-color sequence generator for controlling the illumination of said portion with said second illuminating radiations; processor coupled to said detector for conformally mapping color data provided by said imaging means to said depth data provided by said scanning means for each said spatial coordinates of said first array to provide a color three-dimensional numerical entity comprising a plurality of data points, each data point comprising three-dimensional surface coordinate data and color data associated therewith; a unit for generating manufacturing data for transmission to CAD/CAM device based on said entity a communication port of a communication medium. 31. Device according to claim 30, adapted for determining color and surface topology of a teeth portion. 32. Method for determining the surface topology and associated color of at least a portion of a three dimensional structure, comprising: (a) providing depth data of said portion corresponding to a two-dimensional reference array substantially orthogonal to a depth direction; (b) providing two-dimensional image data of said portion associated with said reference array; (c) ensuring that a spatial disposition with respect to said portion during steps (a) and (b) is substantially fixed; (d) conformally mapping said color data to said depth data for said reference array. 33. Method according to claim 32, wherein in step (c), a minimum time interval is allowed between acquisition of said depth data and acquisition of said image data. 34. Method according to claim 33, wherein said time interval is between about 0 seconds to about 100 milliseconds, preferably between 0 and 50 milliseconds, and more preferably between 0 and 20 milliseconds. 35. Method according to claim 32, wherein said depth data is provided using confocal imaging techniques. 36. Method according to claim 32, comprising: (i) providing a first array of incident light beams defined within said reference array propagating in an optical path leading through a focusing optics and through a probing face; the focusing optics defining one or more focal planes forward said probing face in a position changeable by said optics, each light beam having its focus on one of said one or more focal plane; the beams generating a plurality of illuminated spots on the structure; (ii) detecting intensity of returned light beams propagating from each of these spots along an optical path opposite to that of the incident light; (iii) repeating steps (i) and (ii) a plurality of times, each time changing position of the focal plane relative to the structure; (iv) for each of the illuminated spots, determining a spot-specific position, being the position of the respective focal plane yielding a maximum measured intensity of a respective returned light beam; and (v) generating data representative of the topology of said portion. 37. Method according to claim 36, wherein step (ii) is based on any one of the following:— (A) illuminating said portion with three differently-colored illumination radiations, said illumination radiations being combinable to produce white radiation, capturing a monochromatic image of said portion corresponding to each said illuminating radiation, and combining the monochromatic images to create a full color image, wherein each said illuminating radiation is provided in the form of a second array of incident light beams transmitted towards the portion along an optical path through said probing unit to generate illuminated spots on said portion along said depth direction, wherein said second array is defined within said reference frame; (B) illuminating said portion with substantially white illumination radiation, selectively passing radiation reflected from said portion through a number of color filters, capturing a monochromatic image of said portion corresponding to each said filter, and combining the monochromatic images to create a full color image, wherein said illuminating radiation is provided in the form of a second array of incident light beams transmitted towards the portion along an optical path through said probing unit to generate illuminated spots on said portion along said depth direction, wherein said second array is defined within said reference frame; (C) illuminating said portion with three differently-colored illumination radiations, capturing a monochromatic image of said portion corresponding to each said illuminating radiation, and combining the monochromatic images to create a full color image, wherein each said illuminating radiation is provided in the form of a second array of incident light beams transmitted towards the portion along an optical path through said probing unit to generate illuminated spots on said portion along said depth direction, wherein said second array is defined within said reference frame, and wherein said illuminating radiations are provided by said first illumination source. 38. Method according to claim 37, wherein said second array is arranged to provide color data at a plurality of spatial coordinates substantially corresponding to the spatial coordinates of said first array. 39. Method according to claim 32, further comprising at least one of the following steps:— (A1) using the data representative of said topology for constructing an object to be fitted within said structure; (B1) converting the data representative of said topology into a form transmissible through a communication medium to recipient. 40. Method according to claim 39, wherein in step (A1) said structure is a teeth segment with at least one missing tooth or a portion of a tooth and said object is said at least one missing tooth or the portion of the tooth. 41. Method according to claim 32, comprising repeating steps (i) to (v) for two different surfaces of said structure to provide surface topologies thereof; and combining the surface topologies to obtain color and topological data representative of said structure. 42. Method according to claim 41, for reconstruction of topology of a teeth portion, comprising: determining surface topologies of at least a buccal surface and a lingual surface of the teeth portion; combining the surface topologies to obtain data representative of a three-dimensional structure of said teeth portion.