Robotic alignment method for workpiece measuring systems

What is claimed is: 1. A system including a workpiece measuring machine defining a WMM coordinate system, a workpiece storage apparatus, and a robotic arm having a robotic arm coordinate system that is independent of the WMM coordinate system, the system configured for manipulating a set of workpieces for measurement by the workpiece measuring machine, the system comprising: the robotic arm configurable into an orientation configuration and a placement configuration, wherein: in the orientation configuration, the robotic arm deploys a reference geometry tool; and wherein in the placement configuration, the robotic arm deploys a gripper; a controller operably coupled to the robotic arm, the controller configured: to receive, from the robotic arm in the orientation configuration, measuring space coordinates of each of a set of WMM datum markers on the workpiece measuring machine; to define, based on those measuring space coordinates, a measuring space on the workpiece measuring machine relative to the coordinate system of the robotic arm; and subsequently to operate the robotic arm in the placement configuration to retrieve sequentially, from a storage space, each workpiece in the set of workpieces, and to place each such workpiece into the measuring space of the workpiece measuring machine. 2. The system of claim 1 , wherein the storage apparatus defines a storage coordinate system that is independent of the robotic arm coordinate system, and wherein, in the orientation mode, the controller is further configured to receive, from the robotic arm in the orientation configuration, storage space coordinates of each of a set of storage datum markers on the storage apparatus and to define, based on those storage space coordinates, the storage space. 3. The system of claim 1 : wherein the WMM datum markers are disposed on (i) a WMM or (ii) a pallet; and wherein each WMM datum marker of the set of set of WMM datum markers comprises a kinematic locator having a kinematic cavity comprising one of (a) a rounded cavity or (b) a conical cavity; and wherein the reference geometry tool comprises a tip having a tip geometry that fits precisely into the kinematic cavity to become kinematically constrained in only 2.5 dimensions by the kinematic cavity for determining precise coordinate positions with respect to a robot reference system. 4. The system of claim 3 , wherein the tip geometry comprises sphere that fits precisely into the kinematic cavity such that the convex surface is kinematically constrained by the kinematic cavity. 5. The system of claim 1 , wherein the reference geometry tool comprises a kinematic cavity and each WMM datum marker of the set of WMM datum marker comprises a kinematic locator having a convex surface, the kinematic cavity configured to engage the convex surface of the WMM kinematic locator such that the kinematic cavity is kinematically constrained by the convex surface. 6. The system of claim 1 , wherein the reference geometry tool is permanently affixed at a designated position at the end of the robot arm or its end effector. 7. The system of claim 1 , wherein the reference geometry tool is removably coupled to a designated position at the end of the robot arm or its end effector. 8. The system of claim 1 , wherein the robotic arm simultaneously includes both the gripper and the reference geometry tool, and: in the orientation configuration, the robotic arm deploys the reference geometry tool at a distal end of the arm; and in the placement configuration, the gripper the robotic arm deploys the gripper at the distal end of the arm. 9. The system of claim 8 , wherein the robotic arm comprises a carousel, and both the gripper and the reference geometry tool are simultaneously disposed on the carousel, and the controller is configured to: in the orientation configuration, configure the carousel such that the reference geometry tool is disposed at the distal end of the arm; and in the placement configuration, configure the carousel such that the gripper is disposed at the distal end of the arm. 10. The system of claim 1 , wherein the reference geometry tool comprises an illuminator head, the illuminator head comprising: a first source of visible light configured to project a visible X pattern at a first angle relative to the robotic arm, the X pattern defining a coincident point; and a second source of visible light configured to project a visible line at a second angle relative to the robotic arm, and wherein: the second angle is different from the first angle, such that the visible line intersects the coincident point at a known distance from the illuminator head. 11. A computer-implemented method of operating a measurement system having a workpiece measuring machine including a measuring volume, a workpiece storage apparatus, and a workpiece handling robot having a robot coordinate system, the method comprising: defining a coordinate system common to a measuring space of the workpiece measuring machine, the workpiece storage apparatus, and the workpiece handling robot, defining the coordinate system comprising: orienting the robot to the measuring space of the workpiece measuring machine, wherein orienting the robot to the measuring space of the workpiece measuring machine comprises, for each WMM datum marker in a set of WMM datum markers on the workpiece measuring machine, locating the WMM datum marker in the robot coordinate system, and recording the location of the WMM datum marker; orienting the robot to the workpiece storage apparatus, wherein orienting the robot to the workpiece storage apparatus comprises, for each storage datum marker in a set of storage datum markers, locating the storage datum marker in the robot coordinate system, and recording the location of the storage datum marker; wherein locating each of a plurality of storage datum marker on the workpiece storage apparatus and locating each of a plurality of WMM datum marker on the coordinate measuring machine defines the coordinate system common to a measuring space of the coordinate measuring machine, the workpiece storage apparatus, and the workpiece handling robot, the common coordinate system enabling the robot to accurately retrieve a workpiece from the workpiece storage apparatus and accurately place that workpiece onto a measuring volume of the coordinate measuring machine; automatically retrieving a first workpiece from the workpiece storage apparatus; automatically placing the first workpiece onto the measuring volume of the workpiece measuring machine; and automatically measuring the first workpiece with the workpiece measuring machine. 12. The method of claim 11 , further comprising, prior to orienting the robot to the workpiece storage apparatus and prior to orienting the robot to the measuring space of the workpiece measuring machine: configuring the robot into an orientation configuration, in which the robot includes a reference geometry tool; and wherein locating each of a plurality of storage datum markers on the workpiece storage apparatus comprises locating each of the plurality of storage datum marker on the workpiece storage apparatus with the reference geometry tool; and locating each of a plurality of WMM datum markers on the workpiece measuring machine comprises locating each of a plurality of CMM kinematic locators on the workpiece measuring machine with the same reference geometry tool. 13. The method of claim 12 , wherein: each of a plurality of storage datum markers on the workpiece storage apparatus comprises a storage kinematic locator; each of a plurality of CMM datum markers on the workpiece measuring machine