Inner and outer collimator elements for an optical circuit switch

What is claimed is: 1. An optical circuit switch, comprising: a fiber hole array including an array of receptacles shaped to accept respective optical fibers; a plurality of internal optical fibers enclosed within the optical circuit switch, with one end of each fiber disposed within a respective receptacle of the fiber hole array; a collimating lens array positioned adjacent to the fiber hole array and including a plurality of collimators, wherein each collimator optically couples light into or out of a corresponding one of the internal optical fibers; a MEMS mirror array; a first reflective surface; and a second reflective surface positioned within the optical path between the collimating lens array and the MEMS mirror array, wherein, the fiber hole array, the collimating lens array, the MEMS mirror array, the first reflective surface, and the second reflective surface are positioned relative to one another such that light exiting each of the internal optical fibers passes through its corresponding collimator, reflects off the second reflective surface, and is redirected by a first mirror within the MEMS array towards the first reflective surface, which directs the light back towards a second mirror of the MEMS mirror array, which in turn redirects the light towards a second internal optical fiber via the second reflective surface and a second collimator. 2. The optical circuit switch of claim 1 , further comprising: a plurality of external optical fiber input ports, each coupling to one of the internal optical fibers; and a plurality of external optical fiber output ports, each coupling to one of the internal optical fibers. 3. The optical circuit switch of claim 2 , wherein the MEMS mirror array is configured such that each mirror can be rotated in about two axes by less than about 10° while directing light from an internal optical fiber coupled to an external optical fiber input port to any internal optical fiber coupled to an external optical fiber output port. 4. The optical circuit switch of claim 2 , wherein: each of the internal optical fibers that corresponds to a collimator located around a perimeter of the collimating lens array couples to an external optical fiber output port, and each of the internal optical fibers that corresponds to a collimator located inside the perimeter of the collimating lens array couples to an external optical fiber input port. 5. The optical circuit switch of claim 2 , wherein: each of the internal optical fibers that corresponds to a collimator located around a perimeter of the collimating lens array couples to an external optical fiber input port, and each of the internal optical fibers that corresponds to a collimator located inside the perimeter of the collimating lens array couples to an external optical fiber output port. 6. The optical circuit switch of claim 2 , wherein: each of the internal optical fibers that corresponds to a collimator located within a first contiguous half of the collimating lens array couples to an external optical fiber output port, and each of the internal optical fibers that corresponds to a collimator located within a second contiguous half of the collimating lens array couples to an external optical fiber input port. 7. The optical circuit switch of claim 6 , further comprising driver circuits configured to apply voltages to actuators coupled to each MEMS mirror to cause the MEMS mirrors to rotate in two directions about one axis and in only a single direction about a second axis. 8. The optical circuit switch of claim 2 , wherein within the collimating lens array, collimators corresponding to internal optical fibers coupled to external optical fiber input ports and collimators corresponding to internal optical fibers coupled to external optical fiber output ports alternate according to a checkerboard pattern. 9. The optical circuit switch of claim 1 , wherein the first and second reflective surfaces are configured to reflect light of at least a first wavelength and to be substantially transmissive with respect to a light of a second wavelength, and the optical circuit switch comprises: a light source located behind the second reflective surface and directed towards the MEMS mirror array; and a light detector located behind the first reflective surface to detect light emitted by the light source that has passed through the second reflective surface, off of the mirror array, and through the first reflective surface. 10. The optical circuit switch of claim 9 , further comprising a processor configured to receive an output signal from the light detector and to determine calibration parameters for the MEMS mirror array based on the output signal. 11. An optical circuit switch, comprising: a plurality of external optical fiber input ports; a plurality of external optical fiber output ports; a fiber hole array including an array of receptacles shaped to accept optical fibers; a collimating lens array including a plurality of collimators positioned adjacent to the fiber hole array and configured for directing light into or out of optical fibers disposed in the receptacles of the fiber hole array; a plurality of internal optical fibers enclosed within the optical circuit switch, each optically coupling at one end to an optical fiber input port or an optical fiber output port and disposed at an opposite end into a respective receptacle in the fiber hole array; a MEMS mirror array for selectively controlling optical paths of light exiting respective optical fibers disposed in the fiber hole array such that such light is introduced into different respective optical fibers disposed in the fiber hole array; a first reflective surface, wherein the fiber hole array, the collimator, the MEMS mirror array and the first reflective surface are positioned relative to one another such that light exiting each of the internal optical fibers passes through its corresponding collimator and is redirected by a first mirror within the MEMS array towards the first reflective surface, which directs the light back towards a second mirror of the MEMS mirror array, which in turn redirects the light towards a second internal optical fiber; and a second reflective surface, wherein the second reflective surface is positioned to redirect light passing through the collimator towards the MEMS mirror array. 12. The optical circuit switch of claim 11 , wherein the first reflective surface is a dichroic splitter and the second reflective surface is a dichroic combiner. 13. The optical circuit switch of claim 12 , comprising: a laser and a first lens configured to direct the laser beam through the dichroic combiner to a mirror of the MEMS mirror array; and a second lens and a camera configured to receive a reflection of the laser beam from the mirror. 14. The optical circuit switch of claim 11 , wherein: each of the internal optical fibers that corresponds to a collimator located around a perimeter of the collimating lens array couples to an external optical fiber output port, and each of the internal optical fibers that corresponds to a collimator located inside the perimeter of the collimating lens array couples to an external optical fiber input port. 15. The optical circuit switch of claim 11 , wherein: each of the internal optical fibers that corresponds to a collimator located around a perimeter of the collimating lens array couples to an external optical fiber input port, and each of the internal optical fibers that corresponds to a collimator located inside the perimeter of the collimating lens array couples to an external optical fiber