Source: http://www.google.com/patents/US20020085793?dq=7245279
Timestamp: 2017-08-20 16:38:24
Document Index: 618013924

Matched Legal Cases: ['Application No. 2', 'Application No. 2', 'Application No. 2', 'Application No. 2', 'Application No. 2', 'Application No. 2']

Patent US20020085793 - Optical switch - Google Patents
The invention provides an optical switch having a pair of opposed optical arrays, each optical array including a fixed mirror and a plurality of independently tiltable mirrors, at least one input port for launching a beam of light into the optical switch, said input port being disposed within a respective...http://www.google.com/patents/US20020085793?utm_source=gb-gplus-sharePatent US20020085793 - Optical switch
Publication number US20020085793 A1
Application number US 09/988,538
Also published as CA2328759A1
Publication number 09988538, 988538, US 2002/0085793 A1, US 2002/085793 A1, US 20020085793 A1, US 20020085793A1, US 2002085793 A1, US 2002085793A1, US-A1-20020085793, US-A1-2002085793, US2002/0085793A1, US2002/085793A1, US20020085793 A1, US20020085793A1, US2002085793 A1, US2002085793A1
Original Assignee Thomas Ducellier
Patent Citations (18), Referenced by (2), Classifications (25), Legal Events (1)
US 20020085793 A1
This applications claims priority from Canadian Patent Application No. 2,326,362 filed on Nov. 20, 2000, Canadian Patent Application No. 2,327,862 filed on Dec. 6, 2000, and Canadian Patent Application No. 2,328,759 filed on Dec. 19, 2000.
Optical matrix switches are commonly used in communications systems for transmitting voice, video and data signals. Generally, optical matrix switches include multiple input and/or output ports and have the ability to connect, for purposes of signal transfer, any input port/output port combination, and preferably, for N×M switching applications, to allow for multiple connections at one time. At each port, optical signals are transmitted and/or received via an end of an optical waveguide. The waveguide ends of the input and output ports are optically connected across a switch core. In this regard, for example, the input and output waveguide ends can be physically located on opposite sides of a switch core for direct or folded optical pathway communication therebetween, in side-by-side matrices on the same physical side of a switch interface facing a mirror, or they can be interspersed in a single matrix arrangement facing a mirror.
Establishing a connection between an input port and a selected output port, involves configuring an optical pathway across the switch core between the input ports and the output ports. One known way to configure the optical path is by moving or bending optical fibers using, for example, piezoelectric actuators. The actuators operate to displace the fiber ends so that signals from the fibers are targeted at one another so as to form the desired optical connection across the switch core. The amount of movement is controlled based on the electrical signal applied to the actuators. By appropriate arrangement of actuators, two-dimensional targeting control can be effected.
Another way of configuring the optical path between an input port and an output port involves the use of one or more moveable mirrors interposed between the input and output ports. In this case, the waveguide ends remain stationary and the mirrors are used to deflect a light beam propagating through the switch core from the input port to effect the desired switching. Microelectromechanical devices with mirrors disposed thereon are known in the art that can allow for two-dimensional targeting to optically connect any input port to any output port. For example, U.S. Pat. No. 5,914,801, entitled “Microelectromechanical Devices Including Rotating Plates And Related Methods”, which issued to Dhuler et al. on Jun. 22, 1999; U.S. Pat. No. 6,087,747, entitled “Microelectromechanical Beam For Allowing A Plate To Rotate In Relation To A Frame In A Microelectromechanical Device”, which issued to Dhuler et al. on Jul. 11, 2000; and U.S. Pat. No. 6,134,042, entitled “Reflective MEMS Actuator With A Laser”, which issued to Dhuler et al. on Oct. 17, 2000, disclose microelectromechanical systems (MEMS) having mirrors disposed thereon that can be controllably moved in two dimensions to effect optical switching.
An important consideration in optical switch design is minimizing physical size for a given number of input and output ports that are serviced, i.e., increasing the packing density of ports and beam directing units. It has been recognized that greater packing density can be achieved, particularly in the case of a movable mirror-based beam directing unit, by folding the optical path between the ports and the movable mirror and/or between the movable mirror and the switch interface. Such a compact optical matrix switch is disclosed in U.S. Pat. No. 6,097,860. In addition, further compactness advantages are achieved therein by positioning control signal sources outside of the fiber array and, preferably, at positions within the folded optical path selected to reduce the required size of the optics path.
However, the design of these prior art optical switches is such that the optical components are arranged along the optical path in a “Z-shape” pattern. A “Z-shape” arrangement of optical components is not spatially efficient. Furthermore, the physical size of an optical switch is determined by the number of input and output ports. A plurality of input/output locations are provided so that the input and output beams can enter/exit the switching core. These input/output locations are commonly provided in the form of rectangular or other arrays.
The Z-shape approach for switching an optical signal, requires particular consideration with respect to the physical spacing between the optical elements since the beam of light should not be obstructed by any of the optical elements along the optical path through the switch. It is apparent that this is not an efficient design since physical size requirements are not optimized in such an “off-axis” design.
In accordance with the invention there is provided an optical switch comprising a pair of opposed optical arrays, each optical array including a fixed mirror and a plurality of independently tiltable mirrors, at least one input port for launching a beam of light into the optical switch, said input port being disposed within a respective optical array, at least two output ports for selectively receiving a beam of light from an optical path between the at least one input port and a selected one of the at least two output ports, said at least two output ports being disposed within a respective opposed optical array, and an ATO element having optical power disposed between the pair of opposed optical arrays.
In one embodiment of the present invention, the pair of opposed optical arrays is disposed in respective focal planes of the ATO element. The at least one input port and the at least two output ports are optical bypasses for allowing a beam of light to pass through a respective one of the pair of opposed optical arrays. The pair of opposed optical arrays, the at least one input port, the at least two output ports, and the ATO element are disposed about an optical axis of the ATO element. The fixed mirror of each of the pair of opposed optical arrays is positioned along the optical axis of the ATO element.
In a further embodiment of the present invention, the ATO element has a focal length approximately equal to a near zone length or Rayleigh range of a beam of light incident thereon.
In accordance with the invention there is further provided an optical switch comprising at least one input port for launching a beam of light into the optical switch, at least two output ports for selectively receiving a beam of light from an optical path between the at least one input port and a selected one of the at least two output ports, an ATO element having optical power for performing an angle-to-offset transformation, said ATO element being disposed between the at least one input port and the at least two output ports, a first array of deflectors including a first fixed deflector and a first plurality of independently tiltable deflectors and a second array of deflectors including a second fixed deflector and a second plurality of independently tiltable deflectors, said first and second array of deflectors being disposed in respective focal planes of the ATO element, wherein the first fixed deflector is for receiving a beam of light from the at least one input port via the ATO element and for deflecting a beam of light to one of the second plurality of independently tiltable deflectors via the ATO element, and the second fixed deflector is for receiving a beam of light from one of the first plurality of independently tiltable deflectors via the ATO element and for deflecting a beam of light to a selected one of the at least two output ports via the ATO element, and wherein the first and the second plurality of independently tiltable deflectors are for switching a beam of light along an optical path via the ATO element.
In accordance with a further embodiment of the present invention, a beam of light passes five times through the ATO element along an optical path between the at least one input port and a selected one of the at least two output ports.
The first array of deflectors and the second array of deflectors are disposed on a first MEMS chip and a second MEMS chip, respectively. In accordance with an embodiment of the invention, said deflectors are micro-mirrors.
In another embodiment of the invention, the at least one input port and the at least two output ports are disposed at optical bypass regions of the first and the second MEMS chip, respectively.
In accordance with yet another embodiment of the invention, the ATO element is one of a focusing lens and a GRIN lens. If desired, the GRIN lens is a quarter pitch GRIN lens. If a GRIN lens is employed as the ATO element, the first array of deflectors is disposed at a first end face of the GRIN lens and the second array of deflectors is disposed at a second end face of the GRIN lens. In a further embodiment of the invention, the GRIN lens is a foreshortened GRIN lens for accommodating the first array of deflectors in the first focal plane of the GRIN lens and the second array of deflectors in the second focal plane of the GRIN lens.
In accordance with another aspect of the invention, there is further provided an optical switch comprising at least one input port for launching a beam of light into the optical switch, at least two output ports for selectively receiving a beam of light, an ATO element having optical power and a focal length approximately equal to a near zone length or Rayleigh range of a beam of light incident thereon, and a first array of deflectors and a second array of deflectors for switching a beam of light from the at least one input port to a selected one of the at least two output ports, wherein the switching is performed along an optical path including the first and the second array of deflectors and the ATO element and wherein a beam of light passes five times through the ATO element when switching a beam of light to a selected one of the at least two output ports. In a further embodiment, the first array of deflectors includes a first fixed micro-mirror and a first plurality of tiltable micro-mirrors, and the second array of deflectors includes a second fixed micro-mirror and a second plurality of tiltable micro-mirrors. Preferably, the first and the second array of deflectors are disposed in a respective focal plane of the ATO element.
[0028]FIG. 1 is a schematic presentation of a prior art optical switch having a Z-shaped arrangement of optical components;
[0029]FIG. 2 shows a schematic presentation of an optical switch in accordance with the present invention;
[0030]FIG. 3 is a schematic presentation of an exemplary optical path for a beam of light being switched from an input port to a selected output port;
[0031]FIG. 4 shows a schematic presentation of a preferred embodiment of the optical switch in accordance with the present invention including a GRIN lens;
[0032]FIG. 5 shows a schematic presentation of an array of micro-mirrors provided on a MEMS chip; and
[0033]FIGS. 6a-6 c show a schematic presentation of a Gaussian propagation of the beam of light through a GRIN lens when tilted by −7° (FIG. 6a), 0° (FIG. 6b) and +7° (FIG. 6c).
The present invention expands on the optical switches disclosed in Canadian Patent Application No. 2,326,362 filed on Nov. 20, 2000 and Canadian Patent Application No. 2,327,862 filed on Dec. 6, 2000, the disclosure of which is incorporated herein by reference. The present invention develops the optical architecture of large optical cross-connect structures and applies it to medium and small scale switches to provide a very compact optical switch. For this purpose, two opposing arrays of deflectors including a plurality of independently two-dimensionally tiltable micro-mirrors disposed on a MEMS chip are used in conjunction with an angle-to-offset (ATO) element to provide a switch core in a miniaturized space. The waveguides or fibers are fed through the MEMS chip themselves for compactness, while a single common fixed mirror is added on each opposite MEMS chip for targeting purpose.
Prior art deflection means in transmission are accomplished using a dual mirror arrangement for doubly deflecting the beam. For example, an array of 2 mirrors is used to steer the beam in transmission; a first fixed mirror is used to redirect a beam to a second 2D tiltable mirror that provides the beam steering. Such a dual mirror arrangement is required for each input/output fiber and hence, a clearing is required so as not to obstruct the path of the light beams. In accordance with the present invention, each fixed mirror is replaced with a common fixed mirror placed at the opposed focal planes of the ATO lens. This common fixed mirror is shared for every port. This arrangement obviates a clearance from a fixed mirror to a 2D moveable mirror due to tilting. The optical switch in accordance with the present invention employs two common fixed mirrors, one for the input ports and one for the output ports. Such an arrangement allows to work with normal incidence on mirrors (reduced PDL) and provides a higher fill factor than prior art optical switches. For example, a fill factor of close to 50% is achieved with the switch in accordance with the invention when compared to fill factors of approximately 15-30% for prior art switches using beam steering in transmission.
[0036]FIG. 2 shows a schematic presentation of an optical switch 200 in accordance with the present invention wherein the optical elements are arranged about an optical axis of an ATO element 203. The provision of ATO element 203 affords an optical switch 200 having reduced aberrations.
Switch 200 includes a switch core 201 defined by a pair of opposed arrays of deflectors 204, 210. The first array of deflectors 204 includes a first fixed deflector 206 and a first plurality of 2D tiltable deflectors 208 disposed on a MEMS chip and the second array of deflectors 210 includes a second fixed deflector 212 and a second plurality of 2D tiltable deflectors 214 disposed on a MEMS chip. Optical switch 200 further includes a plurality of input and output waveguides 211 a-d, 213 a-d disposed directly at optical bypasses 215 a-d, 217 a-d of the second and first arrays 210, 204 of the switch core 201. An exemplary input port 202 is shown on the left of FIG. 2 and a plurality of output ports 216, 218, 220, 222 are presented on the right of FIG. 2. As can be seen from FIG. 2, the input port 202 is disposed at optical bypass 215 b of the second array 210 and the output ports 216, 218, 220, 222 are disposed at optical bypasses 217 a-d of the first array 204. Advantageously, the input waveguides 211 a-d terminate in micro-lenses 219 a-d as collimators which are centered on the optical axis of the respective waveguides 211 a-d. Analogously, the output waveguides 213 a-d terminate in micro-lenses 221 a-d as collimators which are centered on the optical axis of the respective waveguides 213 a-d.
However, an individual fiber may function as an input fiber as well as an output fiber depending upon the direction of propagation of an optical signal in a bi-directional communication environment. Accordingly, although this description includes references to input and output fibers for purposes of illustration, it will be understood that each of the fibers may send and/or receive optical signals.
While not essential for the purpose of the present invention, the ATO element preferably has a focal length that substantially corresponds to the near zone length (multi mode) or the Rayleigh range (single mode) of a beam of light propagating through optical switch 200. The use of such ATO element means that the size, i.e. the cross-sectional area, of a beam switched through switch core 201 is substantially the same at the tiltable deflectors 208, 214 and also at the input and output micro-lenses/collimators 219 a-d, 221 a-d. This feature is advantageous for optimizing coupling of the light beams between the input and output waveguides 211 a-d, 213 a-d. This minimizes the beam size requirement because the beam size on the two focal planes is equal, thus enabling a compact switch. The ATO principle is described in further detail in Canadian Patent Application No. 2,326,362, the disclosure of which is herein incorporated by reference.
Each MEMS mirror 208, 214 is preferably provided as a two-dimensionally tiltable micro-mirror which can be selectively oriented, in a manner known in the art, to deflect a light beam received from any mirror and/or bypass of the opposite array 204, 210 to any other mirror and/or bypass of the opposite array 210, 204. In this manner, each MEMS mirror 208, 214 can be selectively positioned to define an optical path between any two mirrors and/or bypasses of the opposite first and second arrays 204, 210. This positioning capability of each MEMS mirror 208, 214 enables highly versatile switching of light beams within the switch core 201.
Turning now to FIG. 3, a schematic presentation of an exemplary optical path for a beam of light being switched from an input port 302 to a selected output port 320 is shown, as it travels through switch core 330 of optical switch 300. A beam of light 301 is launched into the optical switch 300 at input port 302. Input port 302 is disposed at optical bypass 305 on a second array of deflectors/MEMS chip 310. As is seen from FIG. 3, a micro-lens 307 is disposed at the input port 302 to serve as a collimator. Beam 301 traverses through an ATO lens 303 and is directed to a first fixed mirror 306 which is arranged on a first array of deflectors/MEMS chip 304. The first fixed mirror 306 then reflects beam 301 to an independently 2D tiltable micro-mirror 314 on MEMS chip 310 by going back through ATO lens 303. As is seen from FIG. 3, beam 301 comes off at an angle when it is deflected by the first fixed mirror 306 and after passing through the ATO lens 303, it is directed parallel to an optical axis OA until beam 301 reaches micro-mirror 314 on array 310. Micro-mirror 314 is tilted to deflect beam 301 to micro-mirror 308 which is disposed on the first MEMS chip 304 by going back through the ATO lens 303. Micro-mirror 308 sends the beam 301 back in parallel to the optical axis by going through ATO lens 303 and then beam 301 collapses onto the second fixed mirror 312 arranged on the second MEMS chip 310. The second fixed mirror 312 distributes beam 301 to output port 320 by going through the ATO lens 303 again. Output port 320 is disposed at optical bypass 321. A micro-lens 315 is disposed at output port 320 to operate as a collimator. It is apparent from FIG. 3 that the ATO lens 303 is used multiple times to switch a light beam from input port 302 to a selected output port 320. In total, beam 301 has passed 5 times through ATO lens 303 so that the ATO lens 303 fulfils the function of a plurality of lense. For example, the first and the second pass through ATO lens 303 corresponds to a first 1:1 telecentric relay, the third pass through ATO lens 303 corresponds to the ATO switching, and finally, the fourth and fifth pass through ATO lens 303 corresponds to a second 1:1 telecentric relay. This means that the ATO lens 303 fulfils the function of a first telecentric relay, switching, and a second telecentric relay.
By using a same lens multiple times a very compact optical switch is provided. However, in order to accomplish such a compact design, the input and output ports are provided directly on the second and first arrays as described heretofore. The mirrors and the input/output ports share the available space on the first and second arrays which reduces the fill factor. As a result of the reduced fill factor and a maximum packing density of 50% on the first and second arrays, the present invention is used to provide very compact medium to small scale switches, such as compact 16×16, 32×32, and/or 64×64 switches. However, the advantage of further using the ATO lens as a relay lens as well as a telecentric relay obviates the use of such telecentric relay lenses which would otherwise take up more space and hence, very compact small to medium scale switches can be made in accordance with the present invention.
[0047]FIG. 4 shows a schematic presentation of a preferred embodiment of an optical switch 400 in accordance with the present invention wherein the ATO lens is a GRIN lens 402. This embodiment provides an even more compact optical switch. GRIN lens 402 is a ¼ pitch SLW 3.0 SELFOC™ lens having a length of 7.89 mm. A 4×4 SMF input fiber bundle 404, is shown on the left of FIG. 4. It has a pitch of 250 μm. A micro-lens array 406 is disposed on the input fiber bundle 404 to expand the beams to an appropriate diameter. Exemplary dimensions of this micro-lens array 406 are a diameter of 125 μm, a pitch of 250 μm, and an effective focal length of 415 μm. A first array of micro-mirrors 414 including a first common fixed mirror and a first plurality of independently 2D tiltable micro-mirrors is disposed between a micro-lens array 416 and a first end face 412 of lens 402. Exemplary dimension of the micro-mirrors 414, 408 are 125×125 μm2, +/−3.4°, +/−0.2°. The first end face 412 corresponds to a first focal plane of the lens 402. A second end face 410 corresponding to a second focal plane is located on an opposed end face of lens 402. A second array of micro-mirrors 408 including a second common fixed mirror and a second plurality of independently 2D tiltable micro-mirrors is provided between a micro-lens array 406 and the second end face 410. An input fiber bundle 404 having an array of micro-lenses 406 arranged thereon is disposed at the second array of micro-mirrors 408. An output fiber bundle 418 having an array of micro-lenses 416 arranged thereon is disposed at the first array of micro-mirrors 414. The first and the second array of micro-mirrors 408 and 414 are disposed on MEMS chips. These MEMS chips are mounted in the first and second focal plane of the GRIN lens 402, for example by gluing them to the lens 402. GRIN lens 402 operates as an ATO lens and in accordance with an embodiment of the invention, a commercial GRIN lens is used and a respective beam size is computed for this lens. Micro-lenses 408, 414 are determined to determine the beam size.
However, the invention is not intended to be limited to the use GRIN lenses having a focal length approximately equal to the Rayleigh range or near zone length of a beam of light incident thereon. The array of micro-mirrors 414, the array of micro-lenses 416, and the SMF output fiber bundle have the same dimensions as the respective array of micro-mirrors 408, the array of micro-lenses 406, and the SMF output fiber bundle 404 which results in an overall dimension for optical switch 400 of 11 mm×3 mm diameter, excluding the fiber bundles; i.e. a very compact optical switch.
Using a conventional GRIN lens, such as a SELFOC™ SLW 3.0 lens, as the main optical element allows to build a very compact switch and further potentially eases the packaging since conventional coupler-like assembly techniques can be used. The overall footprint for a 16×16 optical switch is less than 11 mm long and 3 mm in diameter excluding the fiber bundles, standard SMF28 on 250 μm pitch.
[0052]FIG. 5 shows a schematic presentation of an array of micro-mirrors provided on a MEMS chip 500 as disposed on a GRIN lens for example. MEMS chip 500 is used as an example to present the first and the second array of micro-mirrors 414, 408 of FIG. 4 in more detail. A common fixed mirror 502 is shown in the center of FIG. 5. The fixed mirror 502 is surrounded by an array of 4×4 of independently 2D tiltable micro-mirrors 504 and beams of light 506 are shown in between neighboring micro-mirrors 504. Exemplary dimensions of MEMS chip 500 are presented in FIG. 5.
[0053]FIGS. 6a-6 c show a schematic presentation of a Gaussian propagation of the beam of light through a GRIN lens when tilted by −7° (FIG. 6a), 0° (FIG. 6b) and +7° (FIG. 6c). FIGS. 6a to 6 c show that the GRIN lens is in agreement with the ATO lens principle in that a certain input mode is maintained at the output. For example, FIG. 6a shows that when a micro-mirror tilts a beam of light by −7° a negative position below the optical axis is reached at the opposed end face of the lens. If the micro-mirror tilts the beam by +7° a positive position above the optical axis is reached (FIG. 6c) and if the micro-mirror tilts the beam by 0° a position on the optical axis is reached (FIG. 6b).
Below follows a brief description of the angle-to-offset (ATO) principle as described through Gaussian beam optics. General Gaussian beam theory states that if the input waist of ½e beam radius W1 is placed at the front focal plane of a lens of focal length F then the output waist of ½e beam radius W2 is located at the back focal plane of the lens. The relationship between these radius sizes is shown in the following equation W 2 = F   λ π   W 1
International Classification G02B6/34, H04Q11/00, G02B6/32, H04J14/02, G02B6/35
Cooperative Classification H04Q2011/0037, H04Q2011/0015, H04J14/02, H04Q2011/0026, H04Q2011/0024, G02B6/3556, H04Q2011/003, H04Q11/0005, G02B6/3512, H04Q2011/0035, H04Q2011/0043, G02B6/32, G02B6/356, H04Q2011/0052, G02B6/3562
European Classification H04J14/02, H04Q11/00P2, G02B6/35E2