Wheel assembly for moving caliper jaw with repeatable force

The invention claimed is: 1. A wheel assembly for moving a caliper jaw relative to a caliper spar with improved user feedback regarding applied measuring force in a caliper, the wheel assembly comprising: a rotary bearing member coupled to the caliper jaw and configured to engage the caliper spar; a rotary actuation member configured to be actuated by a user to apply the measuring force; and a compliant coupling element configured to elastically couple the rotary actuation member to the rotary bearing member; wherein the wheel assembly is configured such that when the rotary bearing member engages the caliper spar a rotational displacement of the rotary actuation member relative to the rotary bearing member generates a deformation of the compliant coupling element which generates a force which is applied to the rotary bearing member and thereby coupled to generate a force on the caliper jaw along its direction of motion which is related to the rotational displacement. 2. The wheel assembly of claim 1 , wherein the rotary bearing member is coupled to a hub capture element that is connected to the caliper jaw. 3. The wheel assembly of claim 2 , wherein the hub capture element is configured to allow the rotary bearing member to move toward the caliper spar such that a spar engagement feature of the rotary bearing member bears on the caliper spar, and to allow the rotary bearing member to move away from the caliper spar such that the spar engagement feature of the rotary bearing member disengages from the caliper spar. 4. The wheel assembly of claim 3 , wherein the spar engagement feature comprises a groove having sides that frictionally engage the caliper spar. 5. The wheel assembly of claim 3 , wherein the wheel assembly is configured such that when the spar engagement feature is disengaged from the caliper spar, the rotary bearing member may rotate freely with the rotary actuation member such that there is no significant rotational displacement of the rotary actuation member relative to the rotary bearing member and no significant deformation of the compliant coupling element. 6. The wheel assembly of claim 1 , further comprising a displacement indicator that is responsive to the rotational displacement between the rotary bearing member and the rotary actuation member. 7. The wheel assembly of claim 6 , wherein the response of the displacement indicator is indicative of the force applied to the rotary bearing member through the compliant coupling element. 8. The wheel assembly of claim 6 , wherein: the compliant coupling element is configured for bi-directional elastic coupling of the rotary actuation member to the rotary bearing member, such that a clockwise rotational displacement of the rotary actuation member relative to the rotary bearing member generates a first polarity deformation of the compliant coupling element which generates a first polarity force applied to the rotary bearing member, and a counter-clockwise rotational displacement of the rotary actuation member relative to the rotary bearing member generates a second polarity deformation of the compliant coupling element which generates a second polarity force applied to the rotary bearing member; and the displacement indicator includes a first polarity portion for indicating a response to clockwise rotational displacement and a second polarity portion for indicating a response to counter-clockwise rotational displacement. 9. The wheel assembly of claim 6 , wherein the displacement indicator is responsive over a rotational displacement range spanning at least 20 degrees between the rotary bearing member and the rotary actuation member. 10. The wheel assembly of claim 6 , wherein the displacement indicator comprises at least one of a visual indicator responsive to the rotational displacement, a tactile sensation generator that provides at least one respective tactile sensation corresponding to a respective rotational displacement, and a sound generator that provides at least one respective sound corresponding to a respective rotational displacement. 11. The wheel assembly of claim 6 , wherein the displacement indicator comprises a pointer element which is coupled to the rotary bearing member and which extends through a clearance opening in the rotary actuation member. 12. The wheel assembly of claim 11 , wherein the pointer element and the clearance opening furthermore provide a rotary stop arrangement wherein the pointer element is rigidly coupled to the rotary bearing member and the clearance opening is sized such that a maximum amount of travel of the pointer element in the clearance opening provides a maximum rotational displacement limit between the rotary bearing member and the rotary actuation member such that deformation of the compliant coupling element is limited to substantially exclude plastic deformation of the compliant coupling element. 13. The wheel assembly of claim 1 , further comprising a rotary stop arrangement configured to provide a maximum rotational displacement limit between the rotary bearing member and the rotary actuation member such that deformation of the compliant coupling element is limited to substantially exclude plastic deformation of the compliant coupling element. 14. The wheel assembly of claim 13 , wherein the rotary stop arrangement is configured to transmit additional force between the rotary actuation member and the rotary bearing member once the maximum rotational displacement limit is reached. 15. The wheel assembly of claim 1 , wherein the wheel assembly is configured such that a change in the rotational displacement of the rotary actuation member relative to the rotary bearing member of 20 degrees generates a related change in force of at least 0.5 newtons and at most 10 newtons on the caliper jaw along its direction of motion. 16. The wheel assembly of claim 1 , wherein the wheel assembly is configured such that it is interchangeable with a rigid thumb wheel that is supplied for use with the caliper, such that the wheel assembly may be coupled without modification to the caliper after the rigid thumb wheel has been removed. 17. The wheel assembly of claim 1 , wherein the rotary bearing member and the rotary actuation member are coaxial. 18. The wheel assembly of claim 1 , wherein the compliant coupling element comprises at least one of a torsion spring, an elastomeric torsion spring, a helical spring arranged in an arc about an axis of rotation of the wheel assembly, or a flexure pivot. 19. A method for applying a measuring force in a caliper, the method comprising: moving a caliper jaw along a direction of motion such that reference surfaces of the caliper contact a workpiece to be measured; operating a wheel assembly while the reference surfaces of the caliper contact the workpiece to be measured, the wheel assembly comprising: a rotary bearing member coupled to the caliper jaw and configured to engage a caliper spar, a rotary actuation member configured to be actuated to apply the measuring force, and a compliant coupling element configured to elastically couple the rotary actuation member to the rotary bearing member, wherein the wheel assembly is configured such that when the rotary bearing member engages the caliper spar a rotational displacement of the rotary actuation member relative to the rotary bearing member generates a deformation of the compliant coupling element which generates a force which is applied to the rotary bearing member and thereby coupled to generate a force on the caliper jaw along its direction of motion