Flexure-based, tip-tilt-piston actuation micro-array

We claim: 1. A flexure-based micro-array comprising: a plurality of micro-assemblies, each comprising: an object; and at least three electrostatic actuation modules for tipping, tilting, and/or piston-actuating the object, each actuation module comprising: a base with first and second electrodes electrically isolated from each other; an electrically conductive lever arm; a first flexure bearing suspending the lever arm adjacent the first and second electrodes so that electrical activation of at least one of the first and second electrodes produces an electrostatic moment of force on the lever arm to resiliently bias the first flexure bearing and pivot the lever arm about a fulcrum, wherein the first flexure bearing comprises stabilizing flexures connecting the anchors to the lever arm at off-axis locations from the fulcrum to additionally constrain the lever arm; and a second flexure bearing connecting the lever arm to the object at a connection location that is different from other connection locations of the other actuation modules so that pivoting the lever arm about the fulcrum induces the second flexure bearing to pivot the object about an object pivot axis defined between two of the other connection locations while the second flexure bearing decouples the lever arm from object displacements induced by two of the other actuation modules connected to the two other connection locations defining the object pivot axis, wherein the plurality of micro-assemblies are arranged with the objects juxtaposed in a substantially 2D array. 2. The flexure-based micro-array of claim 1 , wherein the first flexure bearing comprises a pair of blade flexures arranged along the fulcrum as torsion hinges connecting the lever arm to anchors fixed relative to the base. 3. The flexure-based micro-array of claim 1 , wherein the second flexure bearing has a triangular truss-shape with a wide base connected to the lever arm and an apex connected to the object at the connection location. 4. The flexure-based micro-array of claim 3 , wherein the second flexure bearing comprises two wire flexures spaced from each other at the lever arm to form the wide base, and converging at the apex. 5. The flexure-based micro-array of claim 1 , wherein the second flexure bearing comprises an angled arm flexure having a first blade flexure horizontally cantilevered to the lever arm with a blade surface substantially orthogonal to the fulcrum, and a second blade flexure connected at one end to the first blade flexure and at an opposite end to the object at the connection location and with a blade surface substantially parallel to the fulcrum. 6. The flexure-based micro-array of claim 1 , wherein the lever arm has a first set of comb fingers on one of two lever arm sections divided by the fulcrum and a second set of comb fingers on the other one of the lever arm sections, and the first and second electrodes comprise comb fingers interdigitally positioned between the comb fingers of the first and second sets of comb fingers, respectively, of the lever arm. 7. The flexure-based micro-array of claim 6 , wherein for each of the first and second sets of comb fingers of the lever arm, the comb fingers are connected to adjacent comb fingers of the set across the finger ends. 8. The flexure-based micro-array of claim 6 , wherein for each of the first and second sets of comb fingers of the lever arm, the comb fingers are connected to adjacent comb fingers of the set across an opposite side of the lever arm from the base. 9. The flexure-based micro-array of claim 1 , wherein the object is a micro-mirror having a reflective surface with the actuation modules located on an opposite side thereof, and the plurality of micro-assemblies are arranged with the mirrors juxtaposed to form a substantially gapless micro-mirror array. 10. The flexure-based micro-array of claim 1 , wherein the object is a transmissive element for steering light transmitted therethrough by actuation of the lever arms. 11. The flexure-based micro-array of claim 1 , wherein the object has a hexagonal shape with each hexagonal side juxtaposed to a hexagonal side of an adjacent object to form a honeycomb-shaped micro-array. 12. The flexure-based micro-array of claim 1 , wherein the object has a body, and four blade flexures substantially co-planar to each other and peripherally extending from and alongside the body to respective anchor ends fixed relative to the base. 13. The flexure-based micro-array of claim 1 , wherein each micro-device assembly comprises three electrostatic actuation modules connected to the object at three different connection locations, with the lever arm of each actuation module having a substantially rhombus shape in radial arrangement with the other two substantially rhombus-shaped lever arms so that major axes of the lever arms intersect at equal angles to each other, and the fulcrums are along the respective minor axes. 14. The flexure-based micro-array of claim 13 , wherein the object is a hexagonal micro-mirror having a reflective surface with the actuation module located on an opposite side thereof, and the plurality of micro-assemblies are arranged so that each hexagonal side of the micro-mirror is juxtaposed to a hexagonal side of an adjacent micro-mirror to form a substantially gapless honeycomb-shaped micro-mirror array. 15. The flexure-based micro-array of claim 14 , wherein the first flexure bearing comprises: a pair of blade flexures arranged along the fulcrum as torsion hinges connecting the lever arm to anchors fixed relative to the base; and stabilizing flexures connecting the anchors to the lever arm at off-axis locations from the fulcrum to additionally constrain the lever arm. 16. The flexure-based micro-array of claim 14 , wherein the second flexure bearing has a triangular truss-shape with a wide base connected to the lever arm and an apex connected to the object at the connection location. 17. The flexure-based micro-array of claim 16 , wherein the second flexure bearing comprises two wire flexures spaced from each other at the lever arm to form the wide base, and converging at the apex. 18. The flexure-based micro-array of claim 14 , wherein the lever arm has a first set of comb fingers on one of two lever arm sections divided by the fulcrum and a second set of comb fingers on the other one of the lever arm sections, and the first and second electrodes comprise comb fingers interdigitally positioned between the comb fingers of the first and second sets of comb fingers, respectively, of the lever arm. 19. The flexure-based micro-array of claim 1 , wherein each micro-assembly comprises four electrostatic actuation modules connected to the object at four different connection locations, with the lever arm of each actuation module having a substantially trapezoid shape, and the fulcrums are parallel to and between the trapezoid bases of the respective lever arms. 20. The flexure-based micro-array of claim 19 , wherein the object is a square micro-mirror having a reflective surface with the actuation module located on an opposite side thereof and four blade flexures arranged substantially co-planar to each other and peripherally extending alongside the four sides of the micro-mirror to respective anchor ends fixed relative to the base, and the plurality of micro-assemblies are arranged so that each of the four sides of the square micro-mirror is juxtaposed to a side of an adjacent square micro-mirror to form a substantial