1. Field of the Invention
The present invention is related to optical switches, a method for forming the optical switches, devices that include optical switches, and methods for integrating the switches into cross-connects, multiplexers and other optronic structures.
2. Description of the Related Art
Electronic switches for optical fiber communications are expensive and complicated. They require the signal to be converted from optical to electronic mode before switching can occur. All-optical switches simplify the transmission of the communications signal by avoiding such conversion, but conventional all-optical switches present problems with switching speed, wavelength range or mechanical complexity.
The fastest optical switches are expensive, not only due to the cost to make them, but also because of the power required to operate them. In addition, conventional mirror-based switches are sensitive to vibration because of the complicated actuation mechanism that switches the optical communications signal within the switch. Presently, it is common that large and expensive optical switches are used in the main lines of optical communications transmission circuits, where the large cost is justified by a large volume of data. Soon, optical switches will be needed closer to the consumers' homes and also inside the consumer's house. Thus, there is a need for inexpensive, compact, and stable optical switches.
Some optical fibers are provided near residential developments and in some cases are provided directly into people's homes. However, the present entertainment equipment (TV, set-top receiver, modem, etc.) inside the residences require an electrical signal and thus, the provider of the optical signal conventionally transforms the optical signal provided through the optical fiber into an electric signal that is fed to the residential equipment. To use the full potential of the optical fibers, optical equipment should be used inside the residences. Such an application will need low-cost and high-volume switches.
Also, it is known that optical circuits are being placed in aircrafts and even in automobiles. Such applications could utilize optical switches that are particularly insensitive to vibrations.
The conventional switches are actuator-driven switches, including switches operated electrostatically. Typically, an electrostatic operation is seen in mirror switches, not with moving guides. This typical switch has a fixed input optical guide and a small mirror formed on a movable substrate. The substrate is actuated to move at different positions such that, an incident light from the input optical guide to the mirror, changes with the movement of the mirror. By calculating the movement of the mirror relative to the receiving optical guides, the light from the input optical guide is deviated as desired to one of the receiving optical guides. However, these conventional switches are sensitive to vibrations, and difficult to build and align.
Other optical switches use an incoming fiber and two outgoing fibers attached to an actuation chamber. Electrodes are provided underneath the actuation chamber to move both the incoming fiber and the outgoing fiber to align with each other, as disclosed in Herding et al (“A new micromachined optical fiber switch for instrumentation purposes,” MEMS, MOEMS, and Micromachining, Proc. of SPIE, Vol 5455, Bellingham, Wash., 2004), the entire content of which is included by reference herein.
There are other optical switches where the entire light path of the switch element is made of a single material. These switches include guides fully made of polymers. One example is a polymer switch in which the total internal reflection is used to direct light in one direction. This switch is actuated by a heater by changing the temperature of the polymer and hence changing the index of refraction of a section of the guide. Depending on the index of refraction, light is guided either by total internal reflection to one output guide or by direct transmission into another guide. The similar mechanism of changing the index of refraction can be used to make an interferometer switch. In either case, the design requires heaters, which use more power than an electrostatic mechanism.
For example, Holman et al. disclose a micro-optic switch with lithographically fabricated polymer alignment features for positioning the switch components and optical fibers in U.S. Pat. No. 6,169,827, the entire contents of which is incorporated herein by reference. Holman et al. show a method of bending optical fibers to connect with one of two contact points. However, Holman et al. use complex microfabricated devices that are used to position the optical fiber as required for the switching operation. However, each known MEMS mechanism uses combinations of actuators and guides, that are difficult to align, and the guides are fixed to a substrate.
Marcuse et al. disclose a polymer guide switch and method in U.S. Pat. No. 6,144,780, the entire contents of which is incorporated herein by reference. Marcuse et al. show polymer members being used as light-guides. However, the polymer members of Marcuse et al. are fixed to the substrate and the switch operates through a thermal mechanism.
According to an aspect of the present invention, an optical device for switching an optical signal between a first optical path and a second optical path, includes a substrate, a first guide forming at least a portion of the first optical path, formed on the substrate, and having a movable portion separated from the substrate, a second guide forming at least a portion of the second optical path and disposed adjacent to the first guide, and means for electrostatically bending the movable portion so as to optically couple the first guide to the second guide.
According to another aspect of the present invention, an optical device for switching an optical signal between a first optical path and a second optical path, includes a substrate, a first guide forming the first optical path, formed on the substrate, and having a movable portion separated from the substrate, the movable portion including, an end face disposed at a longitudinal end of the movable portion, and first and second side walls adjoining the end face, a first conducting layer formed on the first side wall of the movable portion, a first electrode protruding from the substrate, opposing the movable portion, and configured to electrostatically bend the movable portion of the first guide when a first voltage is applied between the first electrode and the first conducting layer, and a second guide forming the second optical path, disposed adjacent to the end face of the first guide, and optically coupled to the first guide when the movable portion of the first guide is electrostatically bent by the first voltage.
According to another aspect of the present invention, an optical device for switching an optical signal from an input optical path to one of plural output optical paths, including a substrate, an input guide forming the input optical path, formed on the substrate, and having a movable portion separated from the substrate, the movable portion of the input guide including, an end face disposed at a longitudinal end of the movable portion, and side walls adjoining the end face, conducting layers formed on the side walls of the movable portion, and electrodes connected to the substrate, separated from the input guide, opposing respective ones of the conducting layers, at least partially surrounding the movable portion of the input guide, and configured to electrostatically bend the movable portion of the input guide when a corresponding voltage is applied between one of the electrodes and one of the conducting layers, output guides forming the output optical paths disposed adjacent to the end face of the input guide, and the input guide is optically coupled to a selected one of the plural output guides when the movable portion of the input guide is electrostatically bent.
According to another embodiment of the present invention, a method for switching an optical signal between a first guide and a second guide, includes introducing the optical signal into a movable portion of the first guide formed on a substrate, the movable portion separated from the substrate supporting the movable portion, and applying a first voltage between a first conducting layer formed on a first side wall of the movable portion and a first electrode on the substrate, to electrostatically bend the movable portion of the first guide to optically couple the first guide to a second guide disposed on the substrate and adjacent to the end face of the first guide.
According to another embodiment of the present invention, a method for switching an optical signal from an input guide to one of manifold output optical guides, includes introducing the optical signal into a movable portion of the input guide formed on a substrate, the movable portion separated from the substrate, and applying a voltage between one of conducting layers formed on side walls of the movable portion of the input guide and one electrode of electrodes at least partially surrounding the movable portion of the input guide, to electrostatically bend the movable portion of the input guide to selectively optically couple the input guide to a selected one of the manifold output optical guides.
A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
a-c are schematic representations of an optical switch and a circuit that includes a plurality of optical switches;
Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views,
The guide 1 may be in one embodiment a waveguide as for example, an optical fiber. However, guide 1 may be an optical material that permits total internal reflection of an optical signal, thus the propagation of the optical signal from one end of the guide to the other end of the guide. In other words, a cross-section size of guide 1 can be randomly chosen without taking into account a cut-off frequency. The guide 1 in this embodiment has a rest position in which no voltage is applied to the electrodes 3 and 5. The guide 1 in this embodiment has at least one electrode 2a formed on a side face 1a of the guide 1. The guide 1 may have two electrodes, a first electrode 2a on side 1a and a second electrode 2b, on side face 1b of the guide 1.
The guide 1 in one embodiment is formed, as will be discussed later, to have (i) an end face 1c, and (ii) side faces 1a and 1b adjacent to the end face 1c such that the end face 1c and the adjacent side faces of the guide 1 are movable, i.e., form a movable portion 1d. In other words, in this embodiment a distal portion of the guide is movable and has a cantilever structure.
In this way, the end face 1c and an adjacent portion of the end face may bend towards the electrodes 3 or 5 when an appropriate voltage is applied between electrodes 2a and 5 or electrodes 2b and 3. In one embodiment, block electrode 3 can have the body made of an insulating material and an electrically conductive part 3-1 is formed on a face of the block electrode 3, with an insulator 3-2 covering the conductive part 3-1 to prevent direct contact between the conductive part 3-1 and the electrode 2b. By applying the appropriate voltage (as will be discussed later), the end face 1c of the guide 1 moves and aligns with another guide 7 or 9 (see
According to this embodiment, no heaters or rods are necessary to bend guide 1. According to this embodiment, electrodes 2a and 2b are formed integrally with guide 1 such that guide 1 itself is the actuator. Also, the switch shown in this embodiment has a moving switching element which is held firmly in place by the applied electrostatic force. Thus, the device of this embodiment is not sensitive to vibrations.
In one embodiment, a fluid medium fills the space between the ends of the input guide 1 and the output guides 7 and 9 to limit reflections at the interface between the ends and a gap space between the guides. To perform this function, the index of refraction of the medium may be greater than that of air, but less than that of light-conducting core of the light guides. Examples of such possible media are index-matching fluids LS-5229 and LS-5241-10 (available from NuSil Technology, Wareham, Mass.), with index of refraction values of approximately 1.3 and 1.4, respectively.
In one embodiment, a conductive metal electrode 6 is provided in the substrate 4, as will be shown in more details in
In one embodiment, the movable portion 1d of the light guide has dimensions of approximately 8 μm×10 μm×700 μm. This yields a volume of 5.6×10+4 μm3 or 5.6×10−5 mm3 or 5.6×10−8 cm3. A typical density for transparent, unfilled, polyimide that may be used in the optical switch is 1.42 g/cm3. This yields a mass of about:
5.6×10˜8 cm3×1.42 g/cm3=8×10−8 g.
This example is for illustrative purposes and not to limit the disclosed movable portion to a mass as calculated above. The length of the movable portion may also be in a range from 500 to 1500 μm. This would yield a range in mass from about 5.7×10−8 g to 1.7×10−7 g. In addition, the cross-sections of the light guides may be square, rectilinear, or other designed section.
One feature of the optical switch shown in
Based on this alignment, when an appropriate voltage is applied between electrode 2b of guide 1 and electrode 3, the guide 1 is bent to the position shown in
Electrode blocks 3 and 5 in one embodiment can be positioned to have a V shaped, oblique position as shown in
According to another embodiment, guide 1 is aligned to guide 7 in a neutral position and aligned to the guide 9 when a voltage is applied between guide 1 and electrode block 5. For this embodiment, there is no need for a second electrode block 3. Guide 1 is removed from the guide 9 by reducing the voltage difference to zero between electrode block 5 and electrode 2a on guide 1. Thus, due to the elastic force generated by the bending of the movable portion, guide 1 returns to its neutral position.
The optical switch is formed on a substrate, which might be a portion of a silicon wafer as will be discussed later. The substrate can be packaged in conventional ways, for example, by connecting optical fibers to the input and output guides on the substrate, using for example V-grooves in the silicon to locate the optical fibers. Polymer guides take the light from the input fibers into the switching area 25 and from the switching area to other optical elements and to the output fibers. The guides are attached to the surface of the substrate 27 but are optically separated from the surface by a cladding layer. Top and side faces of the guides are immersed in air or some other fluid of lower index of refraction than the guides, hence creating effective optical cladding around the guides. In this way, light is carried along the guide without loss. Optionally, a cladding layer is coated over the optical guides.
Next, a method of using the switch shown in
In the switching region 25, the two electrode blocks 3 and 5 are placed on either side of the input guide 1. These electrode blocks 3 and 5 permit a voltage to draw the end of the input guide 1 (movable portion) toward whichever electrode block is electrically charged. In this way, the electrode blocks also serve as stopping blocks, holding the input guide in a fixed position. The two fixed positions are arranged so that the light coming from the input guide 1 is directed into one of two output guides 7 and 9. A central neutral position of the guide 1 is not connected to any output, providing an “off” position of the switch. All of the electrodes and guides can be fabricated using the same polymer layer in the micro-fabrication process. To allow for electrostatic operation of the input guide 1 in the switching region 25, a metal such as for example Al and/or Au is disposed (e.g. angle-evaporated) onto a short section of the input guide 1, near the electrode blocks 3 and 5, and on electrode blocks sides facing the guide. The metal may include other materials, such as a thin layer of Titanium (for adhesion) followed by a thicker layer of Tungsten.
The metal electrodes may be connected to outside electrical contact pads 13, 15, and 21. In this way, a structure is achieved in which guide 1 can be drawn to left or right depending on the voltages placed on electrostatic blocks 3 and 5.
In the region of the switch operation 25, the cantilevered input guide is detached from the surface of the substrate, allowing the movable portion 1d to move. This movable portion of the guide 1 is detached from the surface of the substrate 27 by using a removable material during the micro fabrication process, as will be described below. This removable material is specific to the area where the switching action takes place and the remainder of the guide 1 remains attached to the surface of the substrate 27 by the cladding layer.
The operation of the switch shown in
A similar 50 V voltage can be placed on the opposite electrode block to draw the guide across to the opposite electrode block, while removing the 50 V applied to the first electrode block. In one embodiment, two output guides 7 and 9 are located in such a way that, when the moving guide 1 is next to the electrode block 3, the output of guide 1 is directed into output guide 7. Likewise, when the moving portion of guide 1 is drawn next to electrode block 5, the output of guide 1 is directed to output guide 9.
In one embodiment, output guides 7 and 9 are attached to the surface of substrate 27 through an appropriate cladding layer in the same way as input guide 1. Output guides 7 and 9 may be positioned on the substrate 27 to serve as inputs to additional switches or to other guide circuit elements to make multiplex switching elements. For optical communications, the multiplex switching elements, according to one embodiment, include structures such as cross-connects 35, shown in
The optical switch element as shown in
A portion of input guide 1 and all of the two output guides 7 and 9 are attached to a surface of substrate 25. However, in another embodiment, the end faces of output guides 7 and 9 may also have movable portions that may move relative to the surface of substrate 27 and may have corresponding conducting films and stop electrode blocks to further align the output guides with the input guide 1 or other guides.
The movable portion 1d of the input guide 1 that is near the output guides 7 and 9 is detached from the surface of the substrate 27, forming a cantilever, and this portion is allowed to move. According to one embodiment, the length of the movable portion is less than 1 mm and a distance between the movable portion hanging over the substrate and the substrate is about 1 μm. In general, the length of the movable portion depends on various factors, as for example the stiffness and other mechanical properties of the material from which the guide is made.
The above discussed structure may be extended to a guide having more than two positions, by adding additional electrode blocks. In this respect,
In a further embodiment,
Any combination of electrodes is possible, including but not limited to 2×3 electrodes as shown in
The electrostatic switch design discussed above in one embodiment is used to make an integrated optical cross connect. For simplicity, the two-output switch shown in
Twelve of the processed optical switches can be used to make an integrated 4×4 optical cross connect as shown in
In another embodiment,
The embodiment of the present invention provides a switching structure that takes an input from an optical fiber or other source and directs the signal unambiguously to one of many possible output paths in the same bank of switches or in an adjacent bank of switches. This described structure is simpler and less costly then MEMS mirror switches and faster in operation than typical thermal switches.
Also, according to one embodiment of this invention, a microfabricated array of optical switches 33 (see
In addition, according to one embodiment of this invention, an optical switch array 35 (see
The guides are sized appropriately for their application. For use with single-mode optical fiber, the guides are about 10 μm wide. For use with a multi-mode optical fiber, the guides are about 60 μm wide. Depending on the application, other sizes can be chosen. The length of the switch will vary depending on the width of the fibers and the elasticity of the material from which the fibers are made.
The arrays of switches 33 are fabricated on a plane substrate. Outputs of switch units are sent into inputs of later switch units so that a given input signal can be sent into one of a large number of potential outputs. Plane arrays of switches can be stacked together, such as by “flip-substrate” technology, so that signals from one plane array can be switched into another adjacent array. This increases the density of switches at low cost.
There are a variety of possible configurations for the embodiments of this invention. It is anticipated that the outputs of basic switch units 33 are carried to inputs of further switch units 33, by optical fibers 39, by further guides, or other means. The basic switch units may have a variety of output configurations. Rather than having a neutral center position for the input guide (i.e., for a rest position of the input guide, the end face of the movable portion is not aligned with an end face of an output guide), as in
In this respect, to help maximize the transfer of the optical signal, the ends of the output light guides that face the input light guide are slightly flared. In this way, if the two light guides do not meet in perfect alignment, the flared ends still collect most of the light. While the light guides are generally about 10 μm in width, the flared ends are about 12 μm in width in one embodiment. However, other widths are possible.
Additionally, the output light guides are separated by a distance to limit the possibility of light intended for one output entering another output. In one embodiment, the separation distance is about 18 μm. Selecting a separation equal to the width of the input light guide plus two wavelengths of the transmitted light at each side, for infrared communications wavelengths for example, would yield 10 μm+(2×2×1.5 μm)=16 μm.
Next, a fabrication method of the guide 1 is discussed. The above discussed optical switch may use polymer guides but also other materials, such as but not limited to spin-on glasses.
Making a polymer optical switch as shown in
Above these layers, an additional layer 114 is added and patterned to form the input guide, the two output guides, and the two electrostatic blocks. The next step is to apply the metal 116 for electostatic activation of the structure. One approach is to do an angled evaporation of metal onto the edges of the guide facing the electrostatic electrode blocks and electrode blocks themselves. Also, the metal serves to connect these side elements to contact pads for the control circuits.
The structural design and fabrication process is controlled to mask all of the areas where the metal is not wanted and then later remove other portions of it by conventional physical or chemical etching method. An additional fabrication step is the formation of an insulating sidewall 126 covering the metal sidewalls to prevent shorting. The final fabrication step is to remove the release layer 108, mechanically freeing a portion 1d of the input guide 1.
Future refinements to improve light transmission may include an anti-reflection coating on the ends of the guides to help reduce reflections. Additional changes may also include the use of a fluid surrounding the switch other than air. The index of refraction of the fluid will be chosen to be greater than that of air and less than that of the guides, in order not to defeat the cladding requirement.
The design discussed above is more compact than conventional optical switches. Because the guide is its own actuator, and the stop blocks are short distance apart, many switches can be fabricated on a single wafer. This allows for economy of scale, thus reducing the cost of the switch. Also, this structure allows complex circuits to be made including the switch on a single wafer providing the economy of large-scale integration. Electrostatic activation of the guide assures that the switch requires low power.
The fabrication process of the optical switch disclosed above is discussed in more details with reference to
As shown in
Next, a resist layer is applied to the front side of the wafer and the resist is patterned through a first mask. The purpose of the first mask is to produce a conductive metal electrode below the moving portion of the guide 1 to prevent the guide from bending toward the substrate due to electrostatic attraction.
A Cr layer 104 having a thickness of 1000 Å is formed on the silicone nitride layer 102. If a stress is large in the Cr layer 104, a Cr/Au/Cr combination of layers having a thickness of 150 Å/1000 Å/150 Å may be deposited on the silicone nitride 102 by evaporation. Then, the resist and excess metal is removed with a liftoff process.
Further, a first polyimide layer 106 having a thickness of 1 μm is uniformly coated over the entire wafer. The polyimide is cured after coating. A patterned resist is deposited over the polyimide with a second mask to open vias down to a bottom of a metal electrode. Then the polyimide is ME etched and the resist is removed. Next, an oxide 108 is deposited by PECVD to have a thickness of 1 μm. Another resist is deposited and patterned with a third mask (for the release layer under the moving portion of the guide). The oxide layer 108 is wet etched to form a more sloped edge as shown in
Next, as shown in
As shown in
Optionally, the metal layer could be thinner, to enhance the optical characteristics of the guide, and an extra mask may be used after these steps to deposit and pattern thicker metal for the wirebonding pads.
A second polymide layer 114 is deposited (coated and cured) with a thickness of 9 μm. Optionally, the single polyimide layer 114 can be replaced by a three-layer polymer stack with thin, lower-refractive-index materials at the top and bottom of the stack, cladding the polyimide in the middle to form a core of the guide, where the light is trapped in the polyimide. Parylene is a possible material for the cladding. A Ti/W layer 116 is deposited, for example by sputtering, with a thickness of 3000 Å. A resist is patterned by using a sixth mask to define the guide and the deflection electrodes. The Ti/W layer is used an etch mask for the next step, which is to RIE the 9 μm polyimide layer. Then the layer of Ti/W is RIE etched.
As shown in
A layer 126 of Parylene having a thickness of 4000 Å is deposited to produce a uniform coating over the entire device and then, the layer 126 of Parylene is RIE etched with anisotropic etch, removing Parylene from top surfaces of the guide and leaving Parylene on the sides of the guide, as shown in
As shown in
Thus, by using the above disclosed method, an optical switch as shown in one of
Numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US08/60482 | 4/16/2008 | WO | 00 | 12/8/2009 |
Number | Date | Country | |
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60942747 | Jun 2007 | US |