Positioning goniometry

What is claimed is: 1. A goniometer stage comprising: a base; a roller bearing having a first annular race supported by the base and a concentric second annular race; and a rotor plate configured to support a workpiece and defining a bearing surface contacting the second annular race throughout a selective movement of the rotor plate with respect to the base along an arc defining an axis of rotation that is spaced apart from the rotor plate. 2. The goniometer stage of claim 1 wherein the second annular race rotates around an axis that is fixed with respect to the base. 3. The goniometer stage of claim 1 wherein the roller bearing is a first roller bearing, the apparatus comprising a second roller bearing supported by the base, the bearing surface simultaneously contacting both roller bearings during the selective movement of the rotor plate. 4. The goniometer stage of claim 3 wherein the bearing surface is a first bearing surface, the apparatus comprising a second bearing surface contacting a third roller bearing supported by the base simultaneously as the first bearing surface contacts the first and second roller bearings during the selective movement of the rotor plate. 5. The goniometer stage of claim 4 comprising a fourth roller bearing supported by the base, the second bearing surface simultaneously contacting the third and fourth roller bearings during the selective movement of the rotor plate. 6. The goniometer stage of claim 5 wherein the first and third roller bearings are opposingly disposed at a concave angular relationship to each other. 7. The goniometer stage of claim 5 wherein the roller bearings comprise spindle bearings, each having a fixed spindle attached to the base. 8. The goniometer stage of claim 5 wherein the base forms a securement member attached to the first annular race. 9. The goniometer stage of claim 5 wherein the roller bearings comprise taper bearings. 10. The goniometer stage of claim 5 comprising a bias member operably urging the bearing surfaces against the respective roller bearings. 11. The goniometer stage of claim 10 wherein the bias member comprises a roller frictionally engaged against the rotor plate during the selective movement of the rotor plate. 12. The goniometer stage of claim 5 comprising a motor that operably moves the rotor plate. 13. The goniometer stage of claim 12 comprising a flexible belt coupling the motor to the rotor plate. 14. A positioning apparatus comprising: a base supporting a plurality of discrete roller bearings arranged to collectively form a bearing cradle; a rotor plate configured to support a workpiece and supported by the bearing cradle during selective movement with respect to the base along an arc having an axis of rotation that is spaced apart from the rotor plate; and a drive assembly configured to selectively position the rotor plate at a nominal position and alternatively to rotate the rotor plate more than twenty degrees around the axis of rotation in each of opposing rotational directions from the nominal position. 15. The positioning apparatus of claim 14 wherein the drive assembly is configured to rotate the rotor plate more than thirty degrees in each of the opposing rotational directions. 16. The positioning apparatus of claim 14 wherein the drive assembly comprises a servo motor and a position encoder. 17. The positioning apparatus of claim 16 comprising a flexible belt trained around an output shaft of the encoder motor. 18. The positioning apparatus of claim 17 wherein the flexible belt is connected at both separate ends to the rotor plate. 19. The positioning apparatus of claim 14 wherein the rotor plate is operably urged against the bearing cradle by a spring bias member. 20. A method comprising: obtaining a goniometer stage having a moveable rotor plate that is rotatably supported upon a bearing cradle in a stationary base, the rotor plate configured to support and rotate a workpiece around an offset axis of rotation that is separate from boundaries of the goniometer stage; and selectively rotating the workpiece around the offset axis at least twenty degrees in each of opposing rotational directions from a nominal position.