DE19644918A1 - Micromechanical optical switch - Google Patents

Abstract

The optical switch (1) has at least 2 light beam control devices positioned in overlying planes between a pair of cover plates (2a,2b), at least one of these devices having at least one pivoted mirror (6). The devices are separated from one another by a spacing frame (9), the pivoted mirror acting as an electrode cooperating with a pair of counter-electrodes parallel to the mirror edges, for controlling the pivot movement for switching the optical signals.

Description

The invention relates to a micromechanical optical switch unit.

Optical switches are among others in the documents DE OS 37 42 553 Light, in particular laser beam device and Ver drive and laser workstation system, DE OS 40 29 569 fiber find optical switch.

However, these arrangements only put 1 on n-link presentations.

EP 0 153 243 also includes a switch for light waveguide. An optical element that is in the beam lengang between the ends of the waveguide and the mirror is arranged, moved on a linear path so that the Light beam deflected in the optical element, over the mirror reflected and deflected a second time in the optical element and thus the light beam onto the next but one waveguide to be led.

Disadvantages of this arrangement are the moving optics and on the other hand can only waveguides in a fixed Distance to each other. A free choice of Form 1 from n is not possible.

In the publications DE OS 36 08 135, DE OS 37 16 836, DE OS 40 40 001 and DE OS 42 21 918 are optical switches wrote. Movable mirrors come as on / off switches with fixed assignment of the waveguides. A freely selectable assignment from a variety of waves ladders are not possible.

The invention specified in claim 1 is the problem based, optical information on a micromechanical Distribute, mix, separate components bidirectionally and / or switch.  

This problem is with those listed in claim 1 Features resolved.

The advantages achieved with the invention are in particular in that the information optical signals both simple bidirectional from 1 to 1 as well as from 1 to n, n to 1 or n can be switched to n with one and the same arrangement. The micromechanical design enables one small structure with very short switching times and thus high Switching frequencies.

The layer structure favors an economic structure since the individual layers as functional levels with mainly from the Microelectronics known manufacturing technologies can be.

The layer structure with the op table arrangements allows a universal structure each according to the requirements placed on the component. So can bidirectional switching structures of the form 1 on 1, 1 on n, n on 1 or n on n with one and the same device will be realized. The or the plate-shaped and in one Individual mirrors that can be swiveled are made of electrodes performed so that when placing appropriately trained Counter electrodes on the cover plates and a corresponding one Control a tilt is guaranteed. An additional one Movement mechanism for the plate-shaped and in A single mirror movable with a swivel axis is not necessary.

Advantageous embodiments of the invention are in the patent claims 2 to 11 specified.

A simple structure of the micromechanical optical switch unit with the switching options 1 to n, n to 1 or n to n with n is equal to the number of light guides attached the further development of claim 2. Furthermore  this solution low optical loss of light rays when Continuity. Are several such micromechanical optical Switching units arranged in one level results in a compact design of several micromechanical optical switches units, individually or by optical interconnection in the Can be operated in a network.

The further development of claim 3 guarantees the same Chen distance of the light guide to the prism.

A simple and economical structure using known ones and mature technologies of microelectronics is in the Developments of claims 4 to 6 listed. The plate-shaped and movable in a swivel axis mirrors can be matrix-shaped p × p as well as in one arbitrary ratio p × q to each other, where p and g the number of plate-shaped and in one swivel axis movable individual mirror per edge of the micromechanical optical switching unit. The number of plate-shaped and Individual mirror movable in a swivel axis determines the switching ratio 1 to n, n to 1 or n to n, with n equal to the number of those with the micromechanical optical Switching unit coupled light guide. So trained Micromechanical switching units are easily stackable, so that by at least one optical connection of the micromechanical optical switching units with each other, the switching possible 1 on n, n on 1 or n on n compared to individually formed essential micromechanical optical switching units is increased.

With the arrangement of the pivot axis of the plate-shaped and in a pivoting movable single mirror in symmetry axis of the light guide and thus in the axis of symmetry of the Light beam results in a simple assembly of the match other levels. Both are with points of the faces of the opposing slabs individual and movable in a swivel axis as  even with the same dimensions, they are congruent at the. The light guides on the edges of the optical switch are both as transmitting and receiving elements the light rays can be used. Corrections regarding the Po sition of the light beam to the individual light guides fall. When arranging more than two levels with plate-shaped migen and is movable in a pivot axis mirror a symmetrical deflection of the light rays to the cover plate given.

Furthermore, only three switching states of the plate-shaped and single mirror movable in a swivel axis necessary, so that control is made considerably easier. The three Switching states are tilted against each other by the states or no control characterized.

The stops on the cover plates according to the ref Applications of claims 7 and 8 facilitate control the plate-shaped and movable in a swivel axis cell mirror.

A simple realization of the plate-shaped and in one Swivel axis movable single mirror and torsion bar below Use of well-known and proven technologies of the microelek tronics enable the further development of patent claims 9 and 10.

With the further development of claim 11 arise automatically the swivel space of the plate-shaped and in one Single mirror movable pivot axis towards the cover plates, so that additional spacing frames to be provided for a free Swiveling over an angular range of 0 to 45 ° is not necessary are agile. At the same time, the assembly effort is reduced.

Two embodiments of the invention are in the drawings are shown and are described in more detail below.  

Show it:

Fig. 1 micromechanical optical switching unit with a lumpy appearance and formed a plate-shaped and is movable in a pivot axis of the individual mirrors,

Fig. 2 plan view of the mikrome chanical optical switching unit shown in FIG. 1,

Fig. 3 switching unit with two levels and 3 × 3 plate-shaped and movable in a pivot axis individual mirror per level and

Fig. 4 exploded view of the arrangement of FIG. 3.

A first embodiment of the micromechanical optical switching unit 1 consists essentially of a one-piece optics 3 as the first device influencing the light beams in the first plane and a plate-shaped single mirror 6 movable in a pivot axis as the second device influencing the light beams, one above the other and between two Cover plates 2 a and 2 b are arranged (Dar positions of FIGS. 1 and 2).

The one-piece optics 3 is located in a spacer frame 9 . The light beam reaches the one-piece optical system 3 via at least two light guides 10 arranged in one plane. For this purpose, the light guide 10 in trenches, which are in one of the cover plates 2 a and from the frame 9 corresponding to each other, out. The distance between the light guides 10 decreases continuously in the direction of the one piece optics 3 and ends directly at this. This surface of the one-piece optics 3 is formed in a circular shape towards the light guides 10 . By this measure, the ends of the light guide 10 have the same distance from the center of the one-piece optics 3rd

This itself represents, on the one hand, a totally reflecting prism 4 and, on the other hand, a lens 5. After leaving one of the light guides 10 , the light beam strikes the totally reflecting prism 4 and is at it in the direction of the second device influencing the light rays at an angle of 90 ° distracted. In this direction, the surface of the one-piece optics 3 is a lens 5 . In the focal point of this lens 5 , the plate-shaped individual mirror 6, which is movable in a pivot axis, is arranged. For this purpose, the spacer frame 9 has an opening as an optical transition 12 from the first device influencing the light rays to the second device influencing the light rays.

The plate-shaped and movable in a pivot axis single mirror 6 is suspended on two opposite edges with tig torsion bar 7 in a surrounding frame 8 . The frame 8 including the plate-shaped and movable in a pivot axis single mirror 6 are made of a silicon wafer. The plate-shaped individual mirror 6 that can be moved in a pivot axis and the torsion bar 7 are etched free from a sacrificial layer and the remaining area of the silicon wafer represents the painting for the plate-shaped individual mirror 6 itself that can be moved in a pivot axis and also serves the distance from the cover plate 2 b, so that the plate-shaped and movable in a pivot axis single mirror 6 relative to the cover plate 2 b is freely pivotable.

The plate-shaped and movable in a pivot axis single mirror 6 has an area of 3 × 3 mm ² . The pivot axis of the plate-shaped and movable in a pivot axis A single mirror 6 is perpendicular to the axis of symmetry of the curved surface of the one-piece optics 3 , at which the light guide 10 ends. With the deflection of the plate-shaped and movable in a pivot axis single mirror 6 , the light beam incident thereon via the lens 5 and the totally reflecting prism 4 z. B. to the next to the light beam leaving the light guide 10 .

The plate-shaped and movable in a pivot axis single mirror 6 itself represents an electrode. On the parallel to the plate-shaped and movable in a pivot axis A single mirror 6 arranged cover plate 2 b there are two counter electrodes 11 a and 11 b. These are arranged corresponding to the edges of the plate-shaped individual mirror 6 which are parallel to the axis of symmetry of the pivot axis and which are movable in a pivot axis. With such an arrangement, it can be controlled electrostatically so that it can be pivoted on the electrodes depending on the potential.

The electrodes in the form of the plate-shaped and movable in a pivot axis single mirror 6 and the counter electrodes 11 a and 11 b are connected via electrical conductor tracks with suitable ge on the micromechanical optical switching unit 1 existing contact structures, so that the micro-mechanical optical switching unit 1 from the outside electrically can be connected.

The other ends of the light guides 10 are connected to optical transmitting and / or receiving devices.

A second exemplary embodiment of the micromechanical optical switching unit 1 is characterized in that the first and the second light beam influencing device consist of a plate-shaped individual mirror 6 arranged in a matrix shape and movable in a pivot axis ( FIGS. 3 and 4).

In this exemplary embodiment, a matrix contains three times three plate-shaped individual mirrors 6 that can be moved in a pivot axis. These are suspended in a frame 9 surrounding them and two parallel webs 13 . There are in each case three plate-shaped individual mirrors 6 movable in a pivot axis between frame 8 and web 13 or between two webs 13 one behind the other. The free space between the plate-shaped and movable in a pivot axis individual mirrors 6 also represents the optical transition. The distances between the plate-shaped and movable in a pivot axis individual mirror 6 to each other are the same. The plattenför shaped and movable in a pivot axis single mirror 6 itself is connected to two opposite edges centrally placed torsion bars 7 with the frame 8 or the webs 13 . The size of a plate-shaped individual mirror 6 that is movable in a pivot axis is 1.4 × 1.4 mm ² with a thickness of 30 μm. The entire matrix is part of a silicon wafer, the plate-shaped individual mirrors 6 including the torsion bars 7 , which are movable in a pivot axis, represent parts of a sacrificial layer and are freely etched. The parts of the silicon wafer surrounding the plate-shaped and movable in a pivot axis individual mirror 6 represent the frame 8 and the webs 13 and at the same time form parts of the spacer frame 9 .

Two such matrices are arranged with an additional spacing frame 9 arranged in between so that the lines of symmetry of the pivot axes of the plate-shaped and movable in a pivot axis individual mirrors 6 are at right angles to each other and two plattenför shaped and movable in a pivot axis 6 are congruent.

Further spacing frames are located between the matrices joined together and each of the cover plates 2 a and 2 b arranged above the plate-shaped individual mirrors 6 which are movable in a pivot axis. The spacing frame can be omitted if the cover plates 2 a and 2 b each have corresponding recesses, so that the plate-shaped and movable in a pivot axis individual mirrors can be freely pivoted over an angular range of 0 to at least 45 °. The frame or the cover plates 2 a and 2 b have correspondingly arranged trenches in which the ends of light guides 10 are placed with attached gradient index lenses 14 .

The axes of symmetry of the light guides 10 are at right angles to the axes of symmetry of the pivot axes of the plate-shaped individual mirrors 6 which are movable in a pivot axis and are furthermore placed in the axis of symmetry of the light guide 10 . The light beam has a diameter of 0.8 to 1.0 mm and the plate-shaped and movable in a swivel axis bare individual mirror 6 is 30 microns thick, so that when passing through the light beam with undeflected plate-shaped and movable in a swivel axis 6 whose thickness is deflected becomes. This attenuation of the light beam is negligible overall.

With such a structure of the matrices, three light guides 10 and thus a total of twelve light guides 10 can be connected to the micromechanical optical switch unit 1 per edge and can thus be switched, mixed or unmixed.

The other ends of the light guides 10 are connected to optical transmitting and / or receiving devices.

The plate-shaped and movable in a pivot axis A single mirror 6 are designed as electrodes. On the Deckplat th 2 a and 2 b there are two counter electrodes 11 a and 11 b per plate-shaped and movable in a pivot axis individual mirror 6 . These are arranged corresponding to the parallel to the axis of symmetry of the pivot axis edges of the plat-shaped and movable in a pivot axis individual mirror 6 . With such an arrangement, these can be controlled electrostatically, so that the plate-shaped and movable in a pivot axis individual mirror 6 are pivotable depending on the potential.

The electrodes in the form of the plate-shaped and movable in a pivot axis individual mirror 6 and the counter electrodes 11 a and 11 b are connected via electrical conductor tracks with suitable contact structures present on the micromechanical optical switching unit 1 , so that the micromechanical operating table switching unit 1 is electrically contactable from the outside .

Claims (11)

1. Micromechanical optical switching unit, characterized in that between two cover plates ( 2 a) and ( 2 b) a first and at least one second light beam influencing device are arranged one above the other in one plane, that the second light beam influencing device is at least one plate-shaped and A single mirror ( 6 ) that is movable in a pivot axis is that a spacing frame ( 9 ) is located between the first and the second light beam influencing device, that between the first and the second light beam influencing device in the area of the at least one plate-shaped and in one Swivel axis movable individual mirror ( 6 ) towards the same number of optically free transitions ( 12 ) are present that in the cover plates ( 2 a) and ( 2 b), in the spacer frame ( 9 ) and / or in the planes of the first and second light beams influencing devices trenches are introduced so that in this Lichtl Are placed that the plate-shaped and movable in a pivot axis individual mirror ( 6 ) is designed as an electrode and that at least on the parallel to the plate-shaped and movable in a pivot axis individual mirror ( 6 ) two electrodes arranged parallel to the mirror edges ( 11 a) and ( 11 b). 2. Micromechanical optical switching unit according to claim 1, characterized in that the first light beam influencing device is at least one piece optics ( 3 ) in the form of a prism ( 4 ) with an integrated lens ( 5 ) that at least two ends of trenches Light conductors ( 10 ) at the one-piece optics ( 3 ) end that at right angles to the light guides ( 10 ) and the second light beam influencing device towards the lens ( 5 ) be found that the second light beam influencing device in the beam path of the plate-shaped and movable in a pivot axis individual mirror ( 6 ) is arranged so that the pivot axis is in the axis of symmetry of the light guide ( 10 ), that the plate-shaped and movable in a pivot axis individual mirror ( 6 ) represents an electrode and that parallel to it Counter electrodes ( 11 a) and ( 11 b) each parallel to the axis of symmetry se the pivot axis of the existing edge of the plate-shaped and movable in a pivot axis single mirror ( 6 ) on the parallel arranged cover plate ( 11 b). 3. Micromechanical optical switching unit according to claim 2, characterized in that the integrally formed Optics to the light guide is curved outwards and that the distance between the trenches from one another is formed in one piece optics continuously decreases. 4. Micromechanical optical switching unit according to claim 1, characterized in that the first light rays influencing device from at least one arrangement in which between two opposite ends of light-guiding devices a plate-shaped and movable in a pivot axis that is perpendicular to the beam path, individual mirror ( 6 ) is arranged in such a way that the axes of symmetry of the light beam and the pivot axis of the plate-shaped individual mirror ( 6 ) which can be moved in a pivot axis are in one plane, there is that the second light beam influencing device is at least one arrangement of the same kind, that this by 90 ° is rotated relative to the first in the plane is arranged so that the centers of the plate-shaped and movable in a pivot axis individual mirror ( 6 ) in an axis of symmetry and the undeflected plate-shaped and movable in a pivot axis individual mirror ( 6 ) are parallel to each other that the light guiding devices located at the edges in the form of light guides ( 10 ) via gradient index lenses ( 14 ) are optically connected to transmitting and / or receiving devices that influence the first and second light beams From a stand frame ( 9 ) is that the first and the second light-influencing device between two cover plates ( 2 a) and ( 2 b) that the plate-shaped and movable in a pivot axis individual mirrors ( 6 ) are electrodes, that parallel counter electrodes ( 11 a) and ( 11 b) are arranged on the cover plates ( 2 a) and ( 2 b) per parallel to the axis of symmetry of the pivot axis in front of the present edge of the plate-shaped and movable in a pivot axis individual mirror ( 6 ) and that the spacer frame ( 9 ) and the cover plates ( 2 a) and ( 2 b) contain trenches for the light-guiding devices. 5. Micromechanical optical switching unit according to claim 4, characterized in that a plurality of arrangements in which between two opposite ends of light-guiding devices a plate-shaped and in a pivot axis that is perpendicular to the beam path, movable single mirror ( 6 ) is arranged so that the axes of symmetry of the light beam and the pivot axis of the plate-shaped and movable in a pivot axis single mirror ( 6 ) are in one plane, are arranged in series and in parallel and that the light guides ( 10 ) located at the edges via gradient index lenses ( 14 ) with transmission - And / or receiving devices are optically connected. 6. Micromechanical optical switching unit according to claim 4, characterized in that the same number of Anord openings, in which between two opposite ends of light-guiding devices a plate-shaped and in a pivot axis that is perpendicular to the beam path, be movable single mirror ( 6 ) so is arranged that the axes of symmetry of the light beam and the pivot axis of the plate-shaped and movable in a pivot axis single mirror ( 6 ) are in one plane, for each first and second light beam influencing device and that the light guides located at the edges ( 10 ) above Gradien tenindexlinsen ( 14 ) are optically connected to transmitting and / or receiving devices. 7. Micromechanical optical switching unit according to claim 4, characterized in that there are stops on the deck plates ( 2 a) and ( 2 b) corresponding to the parallel to the pivot axis edges of the plate-shaped and movable in a pivot axis individual mirror ( 6 ). 8. Micromechanical optical switching unit according to claim 7, characterized in that the height of the stops is equal to the distance between the edges of the plate-shaped and movable in a pivot axis parallel to the edges of the individual mirrors ( 6 ) in an angle of 45 ° with respect to the cover plates ( 2nd a) and ( 2 b) tilted states and the cover plates ( 2 a) and ( 2 b). 9. micromechanical optical switching unit according to claims 1 to 6, characterized in that the plate-shaped and movable in a pivot axis individual mirror ( 6 ) over two centered on opposite edges torsion bars ( 7 ) with a plate-shaped and movable in a pivot axis Single mirror ( 6 ) surrounding frame ( 8 ) is connected or that the plate-shaped and movable in a pivot axis individual mirror ( 6 ) via two centrally located on opposite edges torsion bars ( 7 ) are connected to parallel webs ( 13 ). 10. Micromechanical optical switching unit according to claim 9, characterized in that the or the plate-shaped and movable in a pivot axis individual mirror ( 6 ), the gate sionsbalken ( 7 ), the frame ( 8 ) and the parallel webs ( 13 ) with layers provided and structured semi-conductor disc. 11. Micromechanical optical switching unit according to claim 10, characterized in that the frame is a sacrificial layer of the semiconductor wafer and that the one or more plate-shaped and movable in a pivot axis individual mirror ( 6 ) and the torsion bars ( 7 ) are parts of the sacrificial layer.