System and method for field calibration of a vision system imaging two opposite sides of a calibration object

What is claimed is: 1 . A calibration target comprising: a base defining a first side and an opposing second side; a first three-dimensional element projecting from the first side, the first three-dimensional element having a first top; a second three-dimensional element projecting from the second side, the second three-dimensional element having a second top; and a first plane located relative to the first side and a second plane located relative to the second side, wherein the first plane and the second plane are substantially parallel, based upon a machining process that uses the first top face as a basis for forming the second top face with the machining process. 2 . The calibration target as set forth in claim 1 wherein the first plane and the second plane are located on at least one of (a) a flange extending from the base, (b) at least a portion of the base, and (c) the first top and the second top, respectively. 3 . The calibration target as set forth in claim 2 wherein the first plane and the second plane have a predetermined thickness therebetween and are formed by a machining process in which the first plane is the basis for machining the second plane 4 . The calibration target as set forth in claim 3 wherein at least one of the first three-dimensional element and the second three-dimensional element comprises a frustum. 5 . The calibration target as set forth in claim 4 wherein the first three-dimensional element is similar in shape and size to the second three dimensional element and the first three-dimensional element is centered about a common z-axis with respect to the second three dimensional element. 6 . The calibration target as set forth in claim 5 wherein the frustum are discretely identified by an adjacent number, in which even numbers are located on the first side and off numbers are located on the second side. 7 . The calibration target as set forth in claim 3 wherein the machining process is arranged to define a predetermined spacing between the first plane and the second plane. 8 . The calibration target as set forth in claim 7 wherein at least one of the first plane and the second plane is one of ground and planed. 9 . The calibration target as set forth in claim 8 wherein at least one of the first element and the second element defines a textured surface that diffuses incident light thereon. 10 . The calibration target as set forth claim 1 wherein the base includes a discrete first indicia formed adjacent to the first three-dimensional element and a discrete second indicia formed adjacent to the second three-dimensional element. 11 . The calibration target as set forth in claim 1 , further comprising, (a) a plurality of first three-dimensional elements projecting from the first side, the first three-dimensional elements respectively having a first top face defining a plane, and (b) a plurality of a second three-dimensional elements projecting from the second side, the second three-dimensional elements respectively having a second top face defining a plane. 12 . A method for calibrating a vision system having at least a first 3D sensor and a second 3D sensor, respectively imaging each of opposing sides of an object in a scene, comprising the steps of: positioning, within the scene, a calibration target having (a) a first three-dimensional element projecting from the first side, the first three-dimensional element having a first top face defining a plane and (b) a second three-dimensional element projecting from the second side, the second three-dimensional element having a second top face defining a plane, in which the first top face and the second top face are substantially parallel, based upon a machining process that uses the first top face as a basis for forming the second top face with the machining process; acquiring a first image of the first three-dimensional element with the first camera assembly and a second image of the second three-dimensional element with the second camera assembly; and based upon at least the first image and the second image, locating features, and with the features, determining calibration parameters for the first camera assembly and the second camera assembly. 13 . The method as set forth in claim 12 wherein the step of determining comprises using the substantially parallel relationship and a predetermined distance value between the top face and the bottom face as a portion of a calibration computation. 14 . The method as set forth in claim 13 wherein the step of locating features includes locating features of a first plurality of frusta arranged on the first side and a second plurality of frusta arranged on the second side. 15 . The method as set forth in claim 14 wherein the step of locating features includes determining discrete indicia adjacent to respective of the frusta in the first plurality of frusta and the second plurality of frusta. 16 . The method as set forth in claim 14 , further comprising generating calibration parameters that map local coordinate spaces of at least the first 3D sensor and the second 3D sensor to a common coordinate space. 17 . A method for constructing a calibration target for use in a vision system having 3D sensors arranged to image each of opposing sides of an object in a scene, comprising the steps of: providing a calibration target base defining a first side and an opposing second side; forming at least one first three-dimensional element projecting from the first side, the first three-dimensional element having a first top; forming at least one second three-dimensional element projecting from the second side, the second three-dimensional element having a second top; and machining, on the calibration target, a first plane and a second plane parallel to the first plane by mounting the calibration target in registration with the first plane in the surfacing device, so that the first plane and the second plane are substantially parallel and at a predetermined spacing apart. 18 . The method as set forth in claim 17 wherein the first plane is located on the first top and the second plane is located on the second top. 19 . The method as set forth in claim 18 wherein the first three-dimensional element is a first frustum and the second three-dimensional element is a second frustum. 20 . The method as set forth in claim 18 , further comprising, providing a first discrete identifier adjacent to the first frustum and a second discrete identifier adjacent to the second frustum.