Removal of artifacts arising from reflections for intraoral scanner

What is claimed is: 1 . A three-dimensional (3D) scanner system comprising: an intraoral scanner comprising: an elongate wand comprising a distal end configured for insertion into an oral cavity, wherein the elongate wand comprises an opening in a sidewall of the distal end of the elongate wand; and at least one of a window arranged in the opening of the elongate wand or a sleeve mounted on an outside of the elongate wand such that the sleeve covers the opening; and a processor operatively connected to the intraoral scanner, said processor configured to: receive one or more two-dimensional (2D) images generated by the intraoral scanner, the one or more 2D images comprising a) captured structured light reflected off of an intraoral object and b) captured additional light arising from reflections from at least one of the window or the sleeve; and perform three-dimensional (3D) image reconstruction using the captured structured light in the one or more 2D images while excluding the captured additional light in the one or more 2D images based on processing of the one or more 2D images using one or more algorithms. 2 . The 3D scanner system according to claim 1 , wherein the one or more algorithms comprise a 3D image reconstruction algorithm, and wherein the processor is further configured to generate a 3D representation of the intraoral object based on the processing of the one or more 2D images using the 3D image reconstruction algorithm, wherein the 3D image reconstruction algorithm is configured to exclude the captured additional light. 3 . The 3D scanner system according to claim 1 , wherein the intraoral scanner further comprises: one or more structured light projectors coupled to the elongate wand, the one or more structured light projectors configured to project structured light onto the intraoral object; and one or more cameras coupled to the elongate wand, the one or more cameras configured to capture the one or more 2D images. 4 . The 3D scanner system of claim 3 , wherein each camera of the one or more cameras (a) comprises a camera sensor and objective optics comprising one or more lenses, and (b) is configured to focus at an object focal plane that is located between 1 mm and 30 mm from a lens of the one or more lenses that is farthest from the camera sensor. 5 . The 3D scanner system of claim 3 , wherein each structured light projector of the one or more structured light projectors comprises: at least one light source to generate light; and a pattern generating optical element configured to generate structured light responsive to the light being transmitted through the pattern generating optical element. 6 . The 3D scanner system of claim 5 , wherein the pattern generating optical element is configured to generate a distribution of discrete unconnected spots of light at all planes located between 1 mm and 30 mm from the pattern generating optical element when the at least one light source is activated to transmit light through the pattern generating optical element. 7 . The 3D scanner system of claim 5 , wherein the light source is a laser diode. 8 . The 3D scanner system of claim 5 , wherein the light source is a light emitting diode. 9 . The 3D scanner system of claim 1 , wherein the captured structured light comprises a checkerboard pattern. 10 . The 3D scanner system of claim 1 , wherein the captured structured light comprises a distribution of discrete unconnected spots. 11 . The 3D scanner system of claim 1 , wherein sleeve is shaped and sized to be placed over the distal end of the elongate wand, the sleeve comprising an additional window through which light enters and exits the opening when the sleeve is coupled to the distal end of the elongate wand. 12 . The 3D scanner system of claim 11 , wherein: the additional window causes at least some of the captured additional light based on reflection of structured light off of the additional window. 13 . The 3D scanner system of claim 1 , wherein the processor is further configured to: identify a presence of the sleeve based on reflections from the sleeve. 14 . The 3D scanner system of claim 13 , wherein the processor is further configured to: set a focal depth of one or more cameras of the intraoral scanner that generate the one or more 2D images in response to the identified presence of the sleeve. 15 . The 3D scanner system of claim 1 , wherein the sleeve is rotationally asymmetric, and wherein rotational asymmetry of the sleeve is such as to assist the sleeve in correctly being placed over the distal end of the elongate wand such that an additional window of the sleeve is aligned with the opening. 16 . The 3D scanner system of claim 1 , wherein the distal end of the elongate wand and a distal end of the sleeve have a same shape. 17 . The 3D scanner system of claim 1 , further comprising: a fluorescent transparent film on at least one of the window or the sleeve, wherein the fluorescent transparent film causes the captured additional light arising from illumination of the window or the sleeve to have a different wavelength than light projected by the intraoral scanner. 18 . The 3D scanner system of claim 1 , wherein the processor is further configured to: determine whether the sleeve is properly seated on the distal end of the elongate wand. 19 . The 3D scanner system of claim 1 , wherein the processor is further configured to: determine when no sleeve is placed over the distal end of the elongate wand; and perform at least one of: a) output an indication that no sleeve is placed over the distal end of the elongate wand; or b) output a notice to place the sleeve over the distal end of the elongate wand. 20 . A three-dimensional (3D) scanner system comprising: an intraoral scanner comprising: an elongate wand comprising a distal end configured for insertion into an oral cavity, wherein the elongate wand comprises a means for light to enter and exit the intraoral scanner; and a means for preventing contact between internal components of the intraoral scanner and the oral cavity, wherein the means for preventing contact between the internal components of the intraoral scanner and the oral cavity is a transparent means that also enables the light to enter and exit the intraoral scanner; and a means for: a) receiving one or more two-dimensional (2D) images generated by the intraoral scanner, the one or more 2D images comprising a) captured structured light reflected off of an intraoral object and b) captured additional light arising from reflections from the means for preventing contact between the internal components of the intraoral scanner and the oral cavity; and b) performing three-dimensional (3D) image reconstruction using the captured structured light in the one or more 2D images while excluding the captured additional light in the one or more 2D images based on processing of the one or more 2D images using one or more algorithms.