Integrated optical micro-electromechanical systems and methods of fabricating and operating the same
First Claim
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1. An integrated optical apparatus, comprising:
- a micro-electromechanical member formed on a substantially transparent substrate;
a substantially transmissive micro-optical element coupled to the micro-electromechanical member; and
an actuator for positioning said substantially transmissive micro-optical element;
wherein said positioning is caused in a first displacement direction substantially coplanar to a major surface of said micro-electromechanical member in response to a first actuating force; and
wherein said positioning is caused in a second displacement direction substantially coplanar to a major surface of said micro-electromechanical member in response to a second actuating force, the second displacement direction being substantially perpendicular to the first displacement direction.
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Abstract
An apparatus and method of fabricating and operating a micro-electromechanical systems (MEMS) integrated optical structure is disclosed. Micro-optics is integrated with MEMS actuators to provide a building block for a micro-optical communication device. Such micro-optical communication device may realize a variety of optical communication systems including optical interconnects, laser communications, or fiber optic switches. In accordance with one aspect of the present invention, a micro-optical element such as a micro-lens is advantageously integrated with an actuator such as MEMS comb drive actuator to form a MEMS lens assembly. The MEMS lens assembly is further coupled to an optical source which may provide a MEMS integrated micro-optical communication device. This integration substantially obviates the generally needed external or manual positioning of the micro-optical element to align a light beam or an optical signal being emitted from the optical source. The MEMS comb drive actuator, responsive to an actuation force, selectively positions the micro-optical element. By appropriately micro positioning a micro-optical element such as a micro-lens relative to an optical source, such as an input optical fiber or a laser diode, a focused light beam or an optical signal may be coupled to a respective optical fiber or a detector. In one embodiment, a commonly used flip chip module assembly technique may be adapted for bonding the MEMS lens assembly to a carrier substrate, which preferably receives the optical source. The carrier substrate is generally disposed on a host assembly. A flip chip based passive alignment of the MEMS lens assembly could be provided. Additionally, an active alignment of the light beam or optical signal with an optical detector may be provided, which can be maintained through a feedback loop.
135 Citations
52 Claims
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1. An integrated optical apparatus, comprising:
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a micro-electromechanical member formed on a substantially transparent substrate;
a substantially transmissive micro-optical element coupled to the micro-electromechanical member; and
an actuator for positioning said substantially transmissive micro-optical element;
wherein said positioning is caused in a first displacement direction substantially coplanar to a major surface of said micro-electromechanical member in response to a first actuating force; and
wherein said positioning is caused in a second displacement direction substantially coplanar to a major surface of said micro-electromechanical member in response to a second actuating force, the second displacement direction being substantially perpendicular to the first displacement direction. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
one or more fixed combs; and
one or more movable combs fixed to said substantially transmissive micro-optical element and being displaced in response to the at least one actuating force.
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9. The apparatus of claim 8, the comb drive actuator further comprising:
at least one suspension member, each suspension member operably connected at a first end to the one or more movable combs and at a second end to the substrate, thereby suspending the one or more movable combs.
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10. The apparatus of claim 1, wherein said positioning is caused in a third displacement direction coplanar to a major surface of said micro-electromechanical member responsive to a concurrent application of the first and second actuating forces.
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11. A method of fabricating an integrated optical apparatus, comprising:
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forming a micro-electromechanical member having an aperture; and
forming a substantially transmissive micro-optical element interposed at the aperture to provide a micro-electromechanical optical assembly;
wherein forming said micro-electromechanical member includes;
forming a first structural material layer over a substrate;
forming a sacrificial material layer over the first structural material layer; and
forming a second structural material layer over the sacrificial material layer. - View Dependent Claims (12, 13, 14, 15)
releasing said micro-electromechanical optical assembly.
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13. The method of claim 11, wherein forming said substantially transmissive micro-optical element includes:
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forming an optically refractive material layer having a major surface to fill said aperture; and
processing said micro-electromechanical optical assembly for adapting the major surface of said optical material layer into a surface profile determined through at least one parameter.
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14. The method of claim 11, wherein said micro-electromechanical member is formed on a substantially transparent substrate.
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15. The method of claim 14, wherein said substantially transparent substrate is glass or quartz.
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16. A method of fabricating an integrated optical apparatus, comprising:
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forming a micro-electromechanical member having an aperture;
separately forming a substantially transmissive micro-optical element; and
assembling the micro-electromechanical member with the micro-optical element;
wherein forming said micro-electromechanical member includes;
forming a first structural material layer over a substrate;
forming a sacrificial material layer over the first structural material layer; and
forming a second structural material layer over the sacrificial material layer. - View Dependent Claims (17, 18)
forming an optically refractive material layer having a major surface; and
processing said micro-electromechanical optical assembly for adapting the major surface of said optical material layer into a surface profile determined through at least one parameter.
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18. The method of claim 16, wherein said micro-electromechanical member is formed on a substantially transparent substrate.
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19. An optical communication apparatus, comprising:
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an optical source to emit a light beam; and
a micro-electromechanical assembly coupled to the optical source and having a photo-polymer micro-lens to receive the light beam for focusing and selective steering thereof. - View Dependent Claims (20, 21, 22, 23, 24, 25, 26, 27, 28, 29)
a comb drive actuator formed on a substrate to selectively position the transmissive micro-optical element in response to an actuating force applied to said comb drive actuator.
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21. The apparatus of claim 19, wherein the micro-electromechanical assembly is formed on a transparent substrate.
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22. The apparatus of claim 19, wherein the optical source is a laser diode.
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23. The apparatus of claim 19, wherein the optical source is a fiber.
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24. The apparatus of claim 19, wherein the optical source is a vertical cavity surface emitting laser diode.
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25. The apparatus of claim 19, wherein the optical source is an edge emitting laser diode.
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26. The apparatus of claim 20, the comb drive actuator further comprising:
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one or more fixed combs; and
one or more movable combs being displaced in response to the actuating force, said one or more movable combs including a frame to hold said transmissive micro-optical element and at least one suspension member, each suspension member operably connected at a first end to the frame and at a second end to the substrate, thereby suspending said one or more movable combs.
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27. The apparatus of claim 21, wherein the micro-electromechanical assembly comprises support layers.
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28. The apparatus of claim 21, wherein the transmissive micro-optical element is coplanar with a major surface of the micro-electromechanical assembly.
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29. The apparatus of claim 26, wherein the actuating force is an electrostatic force.
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30. An optical communication apparatus, comprising:
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a plurality of optical sources, each of the optical sources emitting a light beam; and
a micro-electromechanical assembly having a photo-polymer micro-lens corresponding to each of the optical sources for focusing and steering respective light beams received at the corresponding transmissive micro-optical elements. - View Dependent Claims (31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44)
a comb drive actuator formed on a substrate to selectively position the transmissive micro-optical elements in response to an actuating force applied to said comb drive actuator.
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32. The apparatus of claim 30, wherein said light beams are steered to provide respective steered light beams for an active alignment, the active alignment dynamically aligns the respective steered light beams in a selected direction in response to the actuating force.
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33. The apparatus of claim 30, wherein the micro-electromechanical assembly is formed on a transparent substrate.
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34. The apparatus of claim 30, wherein the optical sources comprise a laser diode array.
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35. The apparatus of claim 30, wherein the optical sources comprise a fiber array.
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36. The apparatus of claim 30, wherein the optical sources comprise a vertical cavity surface emitting laser diode array.
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37. The apparatus of claim 30, wherein the optical sources comprise an edge emitting laser diode array.
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38. The apparatus of claim 30, wherein each said optical source comprises an input fiber disposed in a fiber optical cross connect switch.
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39. The apparatus of claim 38, the micro-electromechanical assembly performs beam switching of the respective light beams received at the associated input fibers to optically link the received respective light beams to a corresponding output fiber of a plurality of output fibers disposed substantially facing said input fibers of the fiber optical cross connect switch.
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40. The apparatus of claim 31, the comb drive actuator further comprising:
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one or more fixed combs; and
one or more movable combs being displaced in response to the actuating force, wherein said one or more movable combs include a frame to hold said transmissive micro-optical elements and at least one suspension member, each suspension member attached at a first end to the frame and at a second end to the substrate, thereby suspending said one or more movable combs.
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41. The apparatus of claim 32, wherein a spatial alignment for each of the steered light beams is maintained by a corresponding feedback control loop.
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42. The apparatus of claim 33, wherein the micro-electromechanical assembly comprises support layers.
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43. The apparatus of claim 33, wherein said transmissive micro-optical elements are coplanar with a major surface of the micro-electromechanical assembly.
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44. The apparatus of claim 40, wherein the actuating force is an electrostatic force.
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45. An optical communication apparatus, comprising:
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an optical source to emit a light beam;
a micro-electromechanical assembly coupled to the optical source and including a movable drive actuator having a transmissive micro-optical element for focusing and selectively steering the light beam; and
an optical signal sensing device for tracking the steered light beam, the optical signal sensing device providing a feedback signal to dynamically align the steered light beam.
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46. An optical communication apparatus, comprising:
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a plurality of optical sources, each of the optical sources emitting a light beam;
a micro-electromechanical assembly coupled to said plurality of optical sources and including a movable drive actuator having a transmissive micro-optical element corresponding to each of the optical sources for focusing and selectively steering the respective light beams; and
an optical signal sensing device corresponding to each of the optical sources for tracking the respective steered light beams, the optical signal sensing devices providing a feedback signal corresponding to each of the optical sources to dynamically align the respective steered light beams.
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47. A method for fabricating an integrated optical communication apparatus, comprising:
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forming a micro-electromechanical member having an aperture by;
forming a first structural material layer over a substrate;
forming a sacrificial material layer over the first structural material layer;
forming a second structural material layer over the sacrificial material layer;
forming an optical polymer material layer having a major surface to fill said aperture; and
processing said micro-electromechanical optical assembly for adapting the major surface of said optical polymer material layer into a spherical profile determined through at least one parameter;
forming a substantially transmissive micro-optical element interposed at the aperture to provide a micro-electromechanical optical assembly;
releasing said micro-electromechanical optical assembly; and
disposing an optical source proximal to said micro-electromechanical optical assembly. - View Dependent Claims (48, 49)
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50. An optical communication apparatus, comprising:
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an optical source to emit a light beam;
a micro-electromechanical assembly coupled to the optical source and having a transmissive micro-optical element to receive the light beam for focusing and selective steering thereof, wherein the light beam is steered to provide a steered light beam for an active alignment, and the active alignment dynamically aligns the steered light beam in a selected direction responsive to an actuating force; and
a feedback control loop that maintains a spatial alignment of the steered light beam.
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51. An optical communication apparatus, comprising:
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an optical source to emit a light beam;
a micro-electromechanical assembly coupled to the optical source and having a transmissive micro-optical element to receive the light beam for focusing and selective steering thereof; and
an input fiber disposed in a fiber optical cross connect switch. - View Dependent Claims (52)
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Specification
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Current AssigneeTeravicta Technologies Incorporated
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Original AssigneeTeravicta Technologies Incorporated
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InventorsHu, Kai, Hilbert, Claude, Reed, Jason D., Miracky, Robert F.
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Primary Examiner(s)Healy, Brian
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Application NumberUS09/775,867Publication NumberTime in Patent Office991 DaysField of Search385/14, 385/31, 385/33, 385/34, 385/35, 385/25, 385/88, 385/89, 385/92, 385/93, 385/94, 385/129, 385/130, 385/131, 385/132, 385/52, 438/26, 438/27, 438/28, 438/29, 438/31, 359/248, 359/298, 359/319, 359/698US Class Current385/14CPC Class CodesG02B 6/1245 Geodesic lensesG02B 6/32 having lens focusing means ...G02B 6/3524 the optical element being r...G02B 6/3526 the optical element being a...G02B 6/357 Electrostatic force electro...G02B 6/3584 constructional details of a...G02B 6/3588 of the processed beams, i.e...G02B 6/3598 Switching means directly lo...G02B 6/4204 the coupling comprising int...G02B 6/4232 using the surface tension o...G02B 6/4249 comprising arrays of active...G02B 6/43 Arrangements comprising a p...H01L 2224/48091 ArchedH01L 2224/48227 connecting the wire to a bo...H01L 2924/00014 the subject-matter covered ...H01L 2924/01039 Yttrium [Y]H01S 3/101 Lasers provided with means ...H01S 5/005 Optical components external...H01S 5/0071 for beam steering, e.g. usi...H01S 5/02257 using windows, e.g. special...View All
