Integrated picomotor mount

What is claimed is: 1. A compact adjustable mount comprising, a base including a mounting surface on a bottom portion of the base; a stage that is substantially fixed relative to the base in all degrees of freedom except a single linear degree of freedom such that the stage translates in the linear degree of freedom over a predetermined distance with respect to the base, the stage also including a mounting surface on an upper portion of the stage; an elongate threaded drive shaft that includes a longitudinal axis, a threaded length having a threaded outer surface with at least one thread groove concentrically disposed about the longitudinal axis and driven portion having an outer surface, the threaded drive shaft being fixed in an axial direction along the longitudinal axis with respect to the base, disposed within an outer perimeter of the base, fixed in directions transverse to the longitudinal axis with respect to the base and rotatable about the longitudinal axis with respect to the base; a nut which is secured to the stage, which includes a bore disposed about the threaded drive shaft, which includes an engagement structure within the bore that is configured to engage the thread groove of the threaded outer surface of the threaded drive shaft, the nut being secured to the stage in a configuration that prevents rotation of the nut in a rotational direction about the longitudinal axis of the threaded drive shaft such that rotation of the threaded drive shaft relative to the base results in rotation of the thread groove relative to the engagement structure of the nut and axial movement of the nut and stage along the longitudinal axis relative to the base; an inertia drive motor disposed within the base including a first contact surface and a second contact surface, the second contact surface being disposed in a spaced and opposed relation relative to the first contact surface, the first and second contact surfaces being operatively engaged with the driven portion of the threaded drive shaft such that actuation of the inertia drive motor imparts reciprocating motion between the first contact surface and second contact surface resulting in rotational motion of the threaded drive shaft relative to the base; and at least one end cap secured in fixed relation to an end of the threaded drive shaft, the end cap being disposed within the outer perimeter of the base, including a high density material and including a moment of inertia sufficient for efficient operation of the inertial drive motor. 2. The compact adjustable mount of claim 1 further comprising at least one linear bearing assembly operatively disposed between the base and the stage. 3. The compact adjustable mount of claim 2 wherein the at least one linear bearing assembly comprises a pair of linear ball bearing assemblies disposed between respective bearing races of the base and the stage. 4. The compact adjustable mount of claim 1 wherein the engagement structure of the nut comprises a threaded inner bore of the nut that is sized to precisely engage the threaded outer surface of the threaded drive shaft. 5. The compact adjustable mount of claim 1 wherein the threaded outer surface of the threaded length of the threaded drive shaft comprises a nitride coating to improve lubricity and durability of the threaded outer surface. 6. The compact adjustable mount of claim 1 wherein the inertia drive motor comprises a piezoelectric drive motor. 7. The compact adjustable mount of claim 1 wherein the driven portion of the threaded drive shaft comprises circumferential grooves disposed in the outer surface thereof and the first and second contact surfaces of the inertia drive motor comprise grooves configured to engage the circumferential grooves of the driven portion. 8. The compact adjustable mount of claim 1 wherein the at least one end cap comprises a high density material having a density that is greater than or equal to a density of stainless steel. 9. The compact adjustable mount of claim 8 wherein the at least one end cap comprises a material having a density equal to or greater than that of tungsten. 10. The compact adjustable mount of claim 9 wherein the at least one end cap comprises tungsten. 11. The compact adjustable mount of claim 1 comprising a first disk shaped end cap secured to a first end of the threaded drive shaft and a second disk shaped end cap secured to a second end of the threaded drive shaft, each end cap being disposed within an outer lateral perimeter of the base and each end cap comprising a material having a density equal to or greater than that of tungsten. 12. The compact adjustable mount of claim 11 wherein the end caps comprise a combined moment of inertia of about 10 gmm 2 to about 15 gmm 2 . 13. The compact adjustable mount of claim 11 wherein the end caps comprise a combined moment of inertia of about 20 gmm 2 to about 30 gmm 2 . 14. The compact adjustable mount of claim 1 wherein the stage comprises a height from a bottom surface of the base to the mounting surface of the stage of about 0.3 inches to about 1 inch. 15. The compact adjustable mount of claim 1 wherein the stage comprises a transverse outer dimension along a direction of translation and with the stage aligned with the base of about 0.75 inches to about 4 inches. 16. The compact adjustable mount of claim 15 wherein the stage comprises a transverse outer dimension along a direction of translation and with the stage aligned with the base of about 1.5 inches to about 3 inches. 17. The compact adjustable mount of claim 1 wherein the base and stage comprise aluminum. 18. The compact adjustable mount of claim 1 wherein the threaded drive shaft comprises stainless steel. 19. The compact adjustable mount of claim 1 wherein the inertia drive motor is secured to the base so as to allow reciprocating motion between the first contact surface and second contact surface against the outer surface of the driven portion and so as to prevent rotation of the inertia drive motor about the first and second contact surfaces relative to the base. 20. The compact adjustable mount of claim 6 wherein the inertia drive motor comprises a piezoelectric inertia drive motor which comprises: an actuator frame, comprising: a first support element which includes the first contact surface, a second support element which includes the second contact surface, the second contact surface being disposed in a spaced and substantially opposed relation relative to the first contact surface, a bias spring clip which is engaged with the first support element and the second support element and which is configured to provide a resilient restoring force that resists perpendicular displacement of the first contact surface away from the second contact surface, and a piezoelectric element cavity disposed between a first mount surface of the actuator frame and a second mount surface of the actuator frame; and a piezoelectric element which is disposed within the piezoelectric element cavity, which has a first end secured to the first mount surface, which has a second end secured to the second mount surface, which is configured to expand and contract in response to an electrical driver signal transmitted to the piezoelectric element and which is configured such that an expansion or contraction of the piezoelectric element results in respective substantially parallel reciprocating displacement between the first contact surface and the second contact surface. 21. The compact adjustable