AU5541999A

AU5541999A – Planar array optical switch and method
– Google Patents

AU5541999A – Planar array optical switch and method
– Google Patents
Planar array optical switch and method

Download PDF
Info

Publication number
AU5541999A

AU5541999A
AU55419/99A
AU5541999A
AU5541999A
AU 5541999 A
AU5541999 A
AU 5541999A
AU 55419/99 A
AU55419/99 A
AU 55419/99A
AU 5541999 A
AU5541999 A
AU 5541999A
AU 5541999 A
AU5541999 A
AU 5541999A
Authority
AU
Australia
Prior art keywords
optical
fiber
reflective means
array
switch device
Prior art date
1998-06-05
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)

Granted

Application number
AU55419/99A
Other versions

AU760646B2
(en

Inventor
David A Krozier
Herzel Laor
Leo Plouffe
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

AFN LLC

Original Assignee
AFN LLC
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1998-06-05
Filing date
1999-06-04
Publication date
2000-01-05

1999-06-04
Application filed by AFN LLC
filed
Critical
AFN LLC

2000-01-05
Publication of AU5541999A
publication
Critical
patent/AU5541999A/en

2002-12-05
Assigned to AFN,LLC
reassignment
AFN,LLC
Alteration of Name(s) of Applicant(s) under S113
Assignors: ASTARTE FIBER NETWORKS, INC.

2003-05-22
Application granted
granted
Critical

2003-05-22
Publication of AU760646B2
publication
Critical
patent/AU760646B2/en

2019-06-04
Anticipated expiration
legal-status
Critical

Status
Ceased
legal-status
Critical
Current

Links

Espacenet

Global Dossier

Discuss

Classifications

G—PHYSICS

G02—OPTICS

G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS

G02B26/00—Optical devices or arrangements for the control of light using movable or deformable optical elements

G02B26/08—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light

G02B26/0816—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light by means of one or more reflecting elements

G02B26/0833—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light by means of one or more reflecting elements the reflecting element being a micromechanical device, e.g. a MEMS mirror, DMD

G—PHYSICS

G02—OPTICS

G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS

G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings

G02B6/24—Coupling light guides

G02B6/26—Optical coupling means

G02B6/35—Optical coupling means having switching means

G02B6/354—Switching arrangements, i.e. number of input/output ports and interconnection types

G02B6/3554—3D constellations, i.e. with switching elements and switched beams located in a volume

G02B6/3556—NxM switch, i.e. regular arrays of switches elements of matrix type constellation

G—PHYSICS

G02—OPTICS

G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS

G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings

G02B6/24—Coupling light guides

G02B6/26—Optical coupling means

G02B6/32—Optical coupling means having lens focusing means positioned between opposed fibre ends

G—PHYSICS

G02—OPTICS

G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS

G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings

G02B6/24—Coupling light guides

G02B6/26—Optical coupling means

G02B6/35—Optical coupling means having switching means

G02B6/351—Optical coupling means having switching means involving stationary waveguides with moving interposed optical elements

G02B6/3512—Optical coupling means having switching means involving stationary waveguides with moving interposed optical elements the optical element being reflective, e.g. mirror

G—PHYSICS

G02—OPTICS

G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS

G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings

G02B6/24—Coupling light guides

G02B6/26—Optical coupling means

G02B6/35—Optical coupling means having switching means

G02B6/3564—Mechanical details of the actuation mechanism associated with the moving element or mounting mechanism details

G02B6/3584—Mechanical details of the actuation mechanism associated with the moving element or mounting mechanism details constructional details of an associated actuator having a MEMS construction, i.e. constructed using semiconductor technology such as etching

H—ELECTRICITY

H04—ELECTRIC COMMUNICATION TECHNIQUE

H04Q—SELECTING

H04Q11/00—Selecting arrangements for multiplex systems

H04Q11/0001—Selecting arrangements for multiplex systems using optical switching

H04Q11/0005—Switch and router aspects

G—PHYSICS

G02—OPTICS

G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS

G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings

G02B6/24—Coupling light guides

G02B6/26—Optical coupling means

G02B6/35—Optical coupling means having switching means

G02B6/351—Optical coupling means having switching means involving stationary waveguides with moving interposed optical elements

G02B6/3512—Optical coupling means having switching means involving stationary waveguides with moving interposed optical elements the optical element being reflective, e.g. mirror

G02B6/3518—Optical coupling means having switching means involving stationary waveguides with moving interposed optical elements the optical element being reflective, e.g. mirror the reflective optical element being an intrinsic part of a MEMS device, i.e. fabricated together with the MEMS device

G—PHYSICS

G02—OPTICS

G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS

G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings

G02B6/24—Coupling light guides

G02B6/26—Optical coupling means

G02B6/35—Optical coupling means having switching means

G02B6/354—Switching arrangements, i.e. number of input/output ports and interconnection types

G02B6/3542—Non-blocking switch, e.g. with multiple potential paths between multiple inputs and outputs, the establishment of one switching path not preventing the establishment of further switching paths

G—PHYSICS

G02—OPTICS

G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS

G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings

G02B6/24—Coupling light guides

G02B6/26—Optical coupling means

G02B6/35—Optical coupling means having switching means

G02B6/354—Switching arrangements, i.e. number of input/output ports and interconnection types

G02B6/356—Switching arrangements, i.e. number of input/output ports and interconnection types in an optical cross-connect device, e.g. routing and switching aspects of interconnecting different paths propagating different wavelengths to (re)configure the various input and output links

H—ELECTRICITY

H04—ELECTRIC COMMUNICATION TECHNIQUE

H04Q—SELECTING

H04Q11/00—Selecting arrangements for multiplex systems

H04Q11/0001—Selecting arrangements for multiplex systems using optical switching

H04Q11/0005—Switch and router aspects

H04Q2011/0007—Construction

H04Q2011/0024—Construction using space switching

H—ELECTRICITY

H04—ELECTRIC COMMUNICATION TECHNIQUE

H04Q—SELECTING

H04Q11/00—Selecting arrangements for multiplex systems

H04Q11/0001—Selecting arrangements for multiplex systems using optical switching

H04Q11/0005—Switch and router aspects

H04Q2011/0007—Construction

H04Q2011/0026—Construction using free space propagation (e.g. lenses, mirrors)

H—ELECTRICITY

H04—ELECTRIC COMMUNICATION TECHNIQUE

H04Q—SELECTING

H04Q11/00—Selecting arrangements for multiplex systems

H04Q11/0001—Selecting arrangements for multiplex systems using optical switching

H04Q11/0005—Switch and router aspects

H04Q2011/0007—Construction

H04Q2011/0026—Construction using free space propagation (e.g. lenses, mirrors)

H04Q2011/003—Construction using free space propagation (e.g. lenses, mirrors) using switches based on microelectro-mechanical systems [MEMS]

Description

WO 99/66354 PCT/US99/12550 PLANAR ARRAY OPTICAL SWITCH AND METHOD RELATED APPLICATION INFORMATION This application claims priority from co-pending provisional application Serial 5 No. 60/088,075, filed June 5, 1998. FIELD OF THE INVENTION The present invention relates generally to fiber optic switches, and, more particularly, concerns a device and method for direct switching of optical signals between 10 input and output optical fibers with minimal optical losses. BACKGROUND OF THE INVENTION Due to advantages over conventional electrical transmission mediums such as increased bandwidth and improved signal quality, the use of fiber optics in 15 communications networks has become commonplace. However, as with electrical signals transmitted over wires which need to be switched between various wires in order for the signals to reach their intended destinations, optical signals similarly need to be switched between different optical fibers at appropriate junctions so that the optical signals reach their intended destinations. 20 One method of switching an optical signal between fibers is to convert the optical signal to an electrical signal, employ conventional electronic switching components to switch the electrical signal, and then re-convert the electrical signal to an optical signal. An alternative approach is to employ direct optical switching wherein the optical signal is directed between fibers. The latter approach has distinct theoretical advantages, 25 including an increase in switching speed and a reduction in signal degradation, because it eliminates the optical-to-electrical and electrical-to-optical conversions. When implementing direct optical switching, it is desirable to have the capability to switch an optical signal from any one of a number of optical fibers entering a junction (input fibers) to any one of a number of optical fibers exiting a junction (output fibers). 30 Several ways of achieving this have been previously proposed. One way is to bend the ends of the selected input and desired output fibers such that the two fibers point at one another (directly or via a folded optical pathway) providing a direct optical pathway for the optical signal between the fibers. The use of fixed reflectors, such as mirrors, in WO 99/66354 PCT/US99/12550 conjunction with bending the fiber ends has also been previously proposed. The fiber ends are not bent to point at one another, but rather are directed at one or more reflectors so that an optical signal from the input fiber is reflected to the output fiber. 5 SUMMARY OF THE INVENTION One object of the present invention is to provide for direct switching of optical signals between optical fibers. The present inventor has recognized that to achieve efficient and accurate switching of the optical signal when implementing direct optical switching, it is desirable 10 that the optical signal be directed from the input fiber such that it enters the output fiber along an optical pathway that is in substantial alignment with the output fiber. Accordingly, another object of the present invention is to provide for direct switching of optical signals between input and output optical fibers wherein the optical signal enters the output fiber along an optical pathway that is in substantial alignment with the output 15 fiber. The present inventor has also recognized that forming the optical signal into a focused beam, as opposed to a collimated or other diverging signal, before directing it to the output fiber with one or more reflectors is desirable in order to reduce loss of the optical signal and improve effectiveness of the switching operation. Accordingly, a 20 further object of the present invention is to provide for direct switching of optical signals between input and output optical fibers wherein the optical signal emitted from the input fiber is formed into a focused beam before directing it to the output fiber with one or more reflectors. These and other objectives and advantages of the present invention are achieved 25 by various aspects of the present invention. According to one aspect of the invention, first and second reflectors, for example mirrors, are provided wherein the first reflector is associated with the input fiber and the second reflector is associated with the output fiber. The first reflector receives the optical signal from the input fiber and is oriented so that it reflects the optical signal in a manner such that it reaches the second reflector, 30 either directly from the first reflector or by further reflection off of other reflectors. The second reflector receives the reflected optical signal and is oriented so that the optical 2 WO 99/66354 PCTIUS99/12550 signal is further reflected to the output fiber along an optical pathway having an axis that is in substantial alignment with the axis of the output fiber. In another aspect of the present invention, the first reflector does not reflect the optical signal directly to the second reflector. Rather, the optical signal from the input 5 fiber is reflected by the first reflector to a third reflector which then reflects the optical signal to the second reflector. Further reflectors may be employed. For example, in one embodiment, the first reflector reflects the optical signal to a third reflector, which reflects the optical signal to a fourth reflector, which, in turn, reflects the optical signal to the second reflector. 10 In yet another aspect of the present invention, multiple reflectors are arranged into first and second arrays of reflectors, with each reflector of the first array being associated with a separate one of a plurality of input fibers and each reflector of the second array being associated with a separate one of a plurality of output fibers. The reflectors of the first and second arrays are positionable in a plurality of orientations 15 relative to a reference orientation. For example, the reflectors of the first and second arrays may be rotatable about at least one axis of rotation to allow for positioning of the reflectors in a plurality of orientations. An optical signal may be switched between any selected one of the input fibers and any selected one of the output fibers by positioning the reflector of the first array associated with the selected input fiber in an orientation 20 such that the optical signal is reflected, either directly or by additional reflectors, to the reflector of the second array associated with the desired output fiber. Preferably, the reflector of the second array associated with the selected output fiber is correspondingly positioned in an orientation such that the optical signal incident thereon is reflected along an optical pathway having an axis substantially aligned with the desired output fiber. 25 A still further aspect of the present invention involves a beam-forming unit associated with an input fiber and an associated beam-directing system for directing the beam on an optical path towards a selected output fiber. The beam forming unit associated with the input fiber receives the optical signal emitted from the end of the selected input fiber and forms it into a focused beam, as opposed to a collimated or other 30 diverging signal. The focused beam optical signal is then directed by the beam-directing system to the selected output fiber. The output fiber is preferably associated with a lens arranged in a focused configuration relative to the beam-forming unit and the output 3 WO 99/66354 PCT/US99/12550 fiber. It will thus be appreciated that a symmetric optical pathway is defined whereby an optical signal from the input fiber is made to enter the end of the output fiber. This arrangement allows for efficient bi-directional communication between the input and output fibers (the «input» and «output» labels being merely a convenience). 5 One more aspect of the present invention involves a method for switching optical signals between an input fiber and an output fiber. The method involves forming the optical signal into a focused beam, directing the beam towards the output fiber along an optical pathway that is, prior to the beam reaching the output fiber, substantially aligned with the output fiber, and receiving the optical signal on the end of the output fiber. A 10 symmetrical focused beam forming unit comprised of a first focused beam forming unit and a second, substantially identical focused beam forming unit may be employed in the forming and receiving steps to enhance optical signal transmission. The step of directing may be accomplished with two active reflectors each associated with one fiber. These and other aspects and advantages of the present invention will be apparent 15 upon review of the following detailed description when taken in conjunction with the accompanying figures. DESCRIPTION OF THE DRAWINGS Figure 1 is a top view illustrating a 5×5 planar array switch embodiment of the 20 present invention; Figure 2 is a perspective view illustrating a 9×9 matrix array switch embodiment of the present invention having two arrays of reflectors; Figure 3 is a perspective view illustrating a 9×9 matrix array switch embodiment of the present invention having four arrays of reflectors; 25 Figure 4 is a top view illustrating 4×4 planar array switch embodiment of the present invention; Figure 5 is a perspective view illustrating a 16×16 matrix array switch embodiment of the present invention having two arrays of reflectors; Figure 6 is a side view of the embodiment of the present invention shown in 30 Figure 5; Figure 7 is a perspective view illustrating a micro electro mechanical mirror appropriate for use as a reflector in the various embodiments of the present invention; 4 WO 99/66354 PCTIUS99/12550 Figure 8 is a side view illustrating a 4×4 matrix array switch embodiment of the present invention configured for use with one array of input and output fibers; Figure 9 illustrates a collimated beam formed by a collimated beam forming unit; Figure 10 illustrates a focused beam formed by a focused beam forming unit; and 5 Figure 11 illustrates a symmetrical pair of focused beam forming units in optical communication with one another; Figure 12 is a cross-sectional view of a fiber illustrating the relationship between admittance and numerical aperture; Figure 13 illustrates various optical parameters relevant to the present invention; 10 and Figure 14 illustrate an imaging relationship geometry in accordance with the present invention. DETAILED DESCRIPTION 15 The optical switch device and method of the present invention allow for switching optical signals between optical fibers. In a communications network, the fibers entering and exiting a junction may be bundled into one group of input fibers and one group of output fibers. The ends of the input and output fibers may further be arranged into two separate rectangular arrays. However, it should be appreciated that, in communications 20 networks, as well as in other applications, the optical fibers may be arranged in other suitable manners. For example, the ends of the input and output fibers may be mixed together in one rectangular array. Furthermore, an individual fiber may function as an input fiber as well as an output fiber depending upon the direction of propagation of the optical signal in a bi-directional communication environment. Accordingly, although the 25 following description includes references to input and output fibers for purposes of illustration, it will be understood that each of the fibers may send and receive optical signals. In the embodiments of the present invention discussed below individual reflectors arranged into one or more arrays of reflectors may be included. In the discussion that 30 follows, an individual reflector of an array of reflectors will be referenced as the (ij) reflector where i identifies the row and j the column of the specific reflector (for purposes 5 WO 99/66354 PCT/US99/12550 of generality, such two-dimensional nomenclature will be used even in the case of linear arrays). Individual input and output fibers will be referenced in a like manner. Planar Switch 5 Referring now to Fig. 1, there is illustrated one embodiment of an optical switch device 10 in accordance with the present invention. For simplicity of illustration, a linear array switch is illustrated in Fig. 1 and more practical two-dimensional array switches will be discussed below. The optical switch device 10 is adapted to function with a linear array of five optical fibers 12 and a linear array of five optical fibers 14. This switch 10 device 10 is referred to as a 5×5 planar array switch because it may switch an optical signal between any one of the five fibers 12 arranged in a line (and therefore coplanar with one another) and any one of the five fibers 14 also arranged in a line. It should be appreciated that although a 5X5 planar array switch is illustrated, the present invention contemplates, in general, MxN planar array switches wherein an optical signal may be 15 switched between any one of M fibers 12 and any one of N fibers 14 (M may equal N or they may differ). The optical switch device 10 includes a first array 20 of five individual reflectors 22 arranged in a line and a second array 30 of five individual reflectors 32 arranged in a second line. Each of the individual reflectors 22 of the first array 20 corresponds with 20 a separate one the fiber 12. For example, the (1,1) reflector 22 of the first array 20 corresponds with the (1,1) fibers 12. Likewise, each of the individual reflectors 32 of the second array 30 correspond with a separate one of the fiber 14. For example, the (1,1) reflector 32 of the second array 30 corresponds with the (1,1) fibers 14. Signals are switched by the optical switch device 10 between any one of the fiber 25 12 and any one of the fibers 14 in the following manner. A first optical signal (shown diagrammatically by arrow S1) emitted from the (1,1) fibers 12 propagates along an optical pathway 40 to the (1,1) reflector 22 of the first array 20. To switch the first optical signal SI to the (1,1) fiber 14, the (1,1) reflector 22 of the first array 20 is oriented so that first optical signal S1 is reflected along optical pathway 42 to the (1,1) reflector 30 32 of the second array 30. The (1,1) reflector 32 of the second array 30 is correspondingly oriented so that it then reflects the first optical signal S1 along optical pathway 44 to the (1,1) fiber output 14. It is important to note that the axis of optical 6 WO 99/66354 PCT/US99/12550 pathway 44 is in substantial alignment with an axis extending centrally from the (1,1) fiber 14. If the (1,1) reflector 32 of the second array 30 is not properly oriented, first optical signal SI may be reflected along any one of a number of optical pathways not in substantial alignment with the axis of the (1,1) fiber 14, such as optical pathway 50, 5 impairing the switching operation. The (1,1) reflector 32 of the second array 30 could be oriented to direct an optical signal to the (1,5) fiber 14 if desired. However, such an arrangement would not provide optimal optical efficiency because the Brightness Theorem (the Second Law of Thermodynamics as applied in optics) requires that active means (e.g. the reflectors 32 of the second array 30) be employed to condense the 10 photons of the optical signal into a small diameter beam that fits the fiber 14 core. When fiber (1,1) in 12 is aligned to (1,1) in 14, light may travel also from (1,1) of 14 to (1,1) of 12. A second optical signal (shown diagrammatically by arrow S2) emitted from the (1,1) fiber 12 is switched to the (1,5) fiber 14 as follows. Second optical signal S2 15 propagates along optical pathway 40 to the (1,1) reflector of the first array 20 which is oriented so that second optical signal S2 is reflected along optical pathway 46 to the (1,5) reflector of the second array 30. The (1,5) reflector of the second array 30 is correspondingly oriented so that it then reflects second optical signal S2 along optical pathway 48 to the (1,5) fiber 14. As with optical pathway 44, optical pathway 48 is 20 substantial in alignment with an axis extending centrally from the (1,5) fiber 14, and, in this arrangement, signals can also be communicated from (1,5) in 14 to (1,1) in 12. It will be appreciated that illustrated pathway 51 cannot co-exist with pathway 52 as reflector (1,1) of 20 can be in only one orientation at a time. If the (1,5) reflector of the second array 30 is not oriented properly, second optical signal S2 will be reflected along 25 an optical pathway divergent from the axis of the (1,5) fiber 14, such as optical pathway 52, impairing the switching operation. Fig. 4 shows a 4×4 implementation of the optical switch device 10 illustrated in FIG. 1. The optical switch device 10 includes a base 16. Each of the individual reflectors 22 of the first array 20 and reflectors 32 of the second array 30 are attached to 30 the base 16. The reflectors 22, 32 may be rotatable about an axis of rotation perpendicular to the base 16 so that they may be oriented as necessary to switch optical signals. Each of the optical fibers 12, 14 is associated with a separate fiber beam forming 7 WO 99/66354 PCT/US99/12550 unit 70. The fiber beam forming units 70 are comprised of an optical fiber end 72 and a lens 74 spaced apart from and coaxial with the optical fiber end 72. Each lens 74 of the fiber beam forming units 70 associated with the fibers 12 focuses an optical signal, such as visual light or infrared radiation, emitted from the fiber end 72 of its associated fiber 5 12 into a beam 80 incident on the reflector 22 of the first array 20 corresponding to the associated fiber input 12. Likewise, each lens 74 of the fiber beam forming units 70 associated with the fiber 14 receives a beam 80 from the reflector 32 of the second array 30 corresponding with the associated fiber 14 and focuses the optical signal beam 80 onto the fiber end 72 of the associated fiber 14. 10 To switch an optical signal between a selected fiber 12 and a selected fiber 14, the reflector 22 of the first array 20 corresponding with the selected fiber 12 is rotated so that the optical signal beam 80 from the lens 74 of the fibers beam forming unit 70 associated with the selected fiber 12 is reflected to the reflector 32 of the second array 30 corresponding with the selected fiber 14. The reflector 32 of the second array 30 15 corresponding with the selected fiber output 14 is rotated so that it reflects the beam 80 to the lens 74 of the fiber beam forming unit 70 associated with the selected fiber 14. As noted above, it is preferred that the beam 80 of the optical signal propagate along an optical pathway from the reflector 32 of the second array 30 to the lens 74 that is in substantial alignment with the axis of the selected fiber output 14. Once a connection is 20 thereby configured between a fiber 12 and a fiber 14, two-directional communication is possible between the fibers 12 and 14. In the description below, the fibers are sometimes designated as «input fibers» or «inputs» and «output fibers» or «outputs» for purposes of convenience, but it will be appreciated that such switch configurations support and will normally involve two-directional communication between the connected fibers. 25 The optical switch device 10 shown in FIG. 4 may be implemented using micro electro mechanical (MEM) technology. The base 16 may include a circuit board or other support on which MEM chips for each of the reflector arrays 20, 30 are mounted. The fiber inputs and outputs 12, 14 may be positioned in V-grooves defined on the surface of the base 16. The lenses 74 may be Frenel Zone lenses made of silicone that are 30 defined on the surface of the base 16 and propped up to a vertical position in front of the V-grooves such that the optical axis of the each lens 74 is parallel to the surface of the base 16. The reflectors 22, 32 may be mirrors also made of silicone and propped up to 8 WO 99/66354 PCT/US99/12550 a vertical position with the ability to rotate about an axis perpendicular to the base 16. The optical switch device 10 should be constructed so as to maintain the optical signal beams 80 parallel to the surface of the base 16, Small adjustments may be made to the reflectors 22, 32 to achieve this objective. 5 Three-Dimensional Space Switches As may be appreciated, the number of fiber inputs 12 and outputs 14 that can be accommodated by a planar array switch as described above is constrained by the practical limits of arranging fiber beam forming units 70 and reflectors 22, 32 in a line. To 10 accommodate additional input and output fibers, the present invention contemplates the utilization of three-dimensional space. Referring now to Fig. 2 there is shown another embodiment of the optical switch device 110 of the present invention which is adapted to function with nine fiber inputs 112 arranged in a 3×3 rectangular array and nine fiber outputs 114 arranged in a second 15 3×3 rectangular array. This switch device 110 is referred to as a 9×9 matrix switch because it may switch an optical signal from any one of the nine fiber inputs 112 arranged in a matrix having three rows and three columns to any one of the nine fiber outputs 114 arranged in a matrix having three rows and three columns. It should be appreciated that although a 9X9 matrix switch is illustrated, the present invention 20 contemplates, in general, MxN matrix switches wherein an optical signal may be switched from any one of M fiber inputs 112 to any one of N fiber outputs 114 (M may equal N or they may differ). The optical switch device 110 includes a first 3×3 rectangular array 120 of individual reflectors 122 and a second 3×3 rectangular array 130 of individual reflectors 25 132. Each of the individual reflectors 122 of the first array 120 corresponds with a separate one of the fiber inputs 112 and each of the reflectors 132 of the second array corresponds with a separate one of the fiber outputs 114. The reflectors 122, 132 are rotatable about at least two orthogonal axes (here the x-axis and the z-axis of the reference axes illustrated) so that an optical signal may be switched from any one of the 30 nine fiber inputs 112 to any one of the nine fiber outputs 114. For example, an optical signal emitted from the end of the (1,1) fiber input 112 propagates along optical pathway 140 to the (1,1) reflector 122 of the first array 120. The (1,1) reflector 122 is rotated to 9 WO 99/66354 PCT/US99/12550 an orientation such that the optical signal is reflected along an optical pathway to the appropriate reflector 132 of the second array corresponding with the desired fiber output 114. For example, depending upon its orientation, the (1,1) reflector 122 of the first array may reflect the optical signal along optical pathways 142, 144, 146, 148 to the (1,1), 5 (1,3), (3,1) or (3,3) reflectors 132, respectively, which are correspondingly rotated to reflect the signal along optical pathways 150, 152, 154, 156 to the (1,1), (1,3), (3,1) and (3,3) fiber outputs 114, respectively. Optical pathways 150, 152, 154, 156 between the second array 130 and the fiber outputs 114 are in substantial alignment with axes extending centrally from the corresponding fiber outputs 114. 10 A 16×16 implementation of the optical switch device 110 illustrated in FIG. 2 is shown in FIGS. 5 and 6. The first array 120 of reflectors 122 includes a first mirror holder 124. Each of the individual reflectors 122 of the first array 120 is attached to the first mirror holder 124 and is rotatable about at least two orthogonal axes. The second array 130 of reflectors 132 includes a second mirror holder 134. Each of the reflectors 15 132 of the second array 130 is attached to the second mirror holder 134 and is rotatable about at least two orthogonal axes. Each of the optical fiber inputs and outputs 112, 114 is associated with a separate fiber beam forming unit 170. As shown in the side view of FIG. 6, the fiber beam forming units 170 are comprised of an optical fiber end 172 and a lens 174 disposed coaxial with the optical 20 fiber end 172. The fiber beam forming units may also include a cylindrical sleeve 176 which is fitted over the fiber end 172 and lens 174. The lens 174 may be spaced from the fiber end 172 or they may be touching, e.g., in the case of a Graded Index (GRIN) lens or a thick lens. Each lens 174 of the fiber beam forming units 170 associated with the fiber inputs 112 focuses an optical signal, such as visual light or infrared radiation, 25 emitted from the fiber end 172 of its associated fiber input 112 into a beam 180 incident on the reflector 122 of the first array 120 corresponding to the associated fiber input 112. Likewise, each lens 174 of the fiber beam forming units 170 associated with the fiber outputs 114 receives a beam 180 from the reflector 132 of the second array 130 corresponding with the associated fiber output 114 and focuses the optical signal beam 30 180 onto the fiber end 172 of the associated fiber output 114. To switch an optical signal between a selected fiber input 112 and a selected fiber output 114, the reflector 122 of the first array 120 corresponding with the selected fiber 10 WO 99/66354 PCTIUS99/12550 input 112 is rotated so that the optical signal beam 180 from the lens 174 of the fiber beam forming unit 170 associated with the selected fiber input 112 is reflected to the reflector 132 of the second array 130 corresponding with the selected fiber output 114. The reflector 132 of the second array 130 corresponding with the selected fiber output 5 114 is rotated so that it reflects the beam 180 to the lens 174 of the fiber beam forming unit 170 associated with the selected fiber output 114. As noted above, it is important that the beam 180 of the optical signal propagate along an optical pathway from the reflector 132 of the second array 130 to the lens 174 that is in substantial alignment with the axis of the selected fiber output 114. It is also noted that the beam 180 from the fiber 10 112 is aligned with the mirror 122. Fig. 7 shows one of the reflectors 122, 132 of the optical switch device 110 illustrated in FIGS. 2, 5 and 6. While many different types of reflectors having appropriate reflective properties may be employed, the reflector in the illustrated embodiment is a chip mounted, micro electro mechanical (MEM) mirrors such as those 15 manufactured by Texas Instruments. The MEM mirror 410 is constructed of silicone and is mounted on an MEM chip 412. The mirror 410 is capable of controlled rotational movement in two degrees of freedom about two orthogonal axes 414, 416. The orthogonal axes 414, 416 are parallel with the chip surface. Fig. 3 illustrates another embodiment of the optical switch device 210 of the 20 present invention. As with the embodiment illustrated in FIG. 2, this optical switch device utilizes three-dimensional space and is also a 9×9 matrix switch for switching optical signals from any one of nine fiber inputs 212 arranged in a matrix having three rows and three columns to any one of nine fiber outputs 214 arranged in a second matrix having three rows and three columns. However, it should be appreciated that the optical 25 switch device 210 illustrated in FIG. 3 may generally be an MxN matrix switch. The optical switch device 210 includes a first 3×3 rectangular array 220 of nine reflectors 222, a second 3×3 rectangular array 230 of nine reflectors, a third 3×3 rectangular array 240 of nine reflectors 242 and a fourth 3×3 rectangular array 250 of nine reflectors 252. Each of the reflectors 222 of the first array 220 corresponds with a 30 separate one of the fiber inputs 212 and each of the reflectors 252 of the fourth array 250 corresponds with a separate one of the fiber outputs 214. To allow switching of a signal from any one of the fiber inputs 212 to any one of the fiber outputs 214, each of the 11 WO 99/66354 PCT/US99/12550 reflectors 222, 242 of the first and third arrays 220, 240 are rotatable about an axis of rotation parallel with the z-axis of reference illustrated and each of the reflectors 232, 252 of the second and third arrays 230, 250 are rotatable about an axis of rotation parallel with the x-axis of reference illustrated. The reflectors 222, 232, 242, 252 may be of the 5 same type as those illustrated in FIG. 7, with the exception that they need only be free to rotate about one axis. The following examples illustrate how the optical switch device 210 switches an optical signal from any one of the fiber inputs 212 to any one of the fiber outputs 214. An optical signal from the (1,1) fiber input 212 propagates along optical pathway 260 to 10 the (1,1) reflector 222 of the first array 220. To switch the signal to the (1,1) fiber output 214, the (1,1) reflector 222 of the first array 220, the (1,1) reflector 232 of the second array 230, the (1,1) reflector 242 of the third array 240, and the (1,1) reflector 252 of the fourth array 250 are each rotated to appropriate orientations such that the optical signal is reflected along optical pathways 262, 272, 282, 292 from the (1,1) reflector 222 of the 15 first array 220 to the (1,1) reflector 232 of the second array 230 to the (1,1) reflector 242 of the third array 240 to the (1,1) reflector 252 of the fourth array 250 to the (1,1) fiber output 214. To switch the signal to the (1,3) fiber output 214, the (1,1) reflector 222 of the first array 220, the (1,1) reflector 232 of the second array 230, the (1,1) reflector 242 of the third array 240, and the (1,3) reflector 252 of the fourth array 250 are each rotated 20 to appropriate orientations such that the optical signal is reflected along optical pathways 262, 272, 284, 294 from the (1,1) reflector 222 of the first array 220 to the (1,1) reflector 232 of the second array 230 to the (1,1) reflector 242 of the third array 240 to the (1,3) reflector 252 of the fourth array 250 to the (1,3) fiber output 214. To switch the signal to the (3,1) fiber output 214, the (1,1) reflector 222 of the first array 220, the (3,1) 25 reflector 232 of the second array 230, the (3,1) reflector 242 of the third array 240, and the (3,1) reflector 252 of the fourth array 250 are each rotated to appropriate orientations such that the optical signal is reflected along optical pathways 266, 276, 286, 296 from the (1,1) reflector 222 of the first array 220 to the (3,1) reflector 232 of the second array 230 to the (3,1) reflector 242 of the third array 240 to the (3,1) reflector 252 of the fourth 30 array 250 to the (3,1) fiber output 214. To switch the signal to the (3,3) fiber output 214, the (1,1) reflector 222 of the first array 220, the (3,1) reflector 232 of the second array 230, the (3,1) reflector 242 of the third array 240, and the (3,3) reflector 252 of the fourth 12 WO 99/66354 PCTIUS99/12550 array 250 are each rotated to appropriate orientations such that the optical signal is reflected along optical pathways 266, 276, 288, 298 from the (1,1) reflector 222 of the first array 220 to the (3,1) reflector 232 of the second array 230 to the (3,1) reflector 242 of the third array 240 to the (3,3) reflector 252 of the fourth array 250 to the (3,3) fiber 5 output 214. It is important to note that the optical pathways 292, 294, 296, 298 between the reflectors 252 of the fourth array 250 and the fiber outputs 214 are in substantial alignment with axes extending centrally from the corresponding fiber outputs 214. Referring now to Fig. 8, there is shown an additional embodiment of the optical switch device 310 of the present invention. The optical switch device 310 also utilizes 10 three-dimensions and is adapted for switching an optical signal between any one of a number of fibers 312 and any other one of the fibers 312, where the fibers 312 are arranged in a single array. Although a 1×4 linear array of fibers 312 is depicted, the optical switch device 310 can be adapted for use with a rectangular or other planar array of fibers 312. It should be appreciated that each of the fibers 312 can function as a 15 transmitting fiber and a receiving fiber depending upon the direction of propagation of the optical signal. Thus, the switch device 310 depicted in Fig. 8 may be referred to as a 4×4 matrix array switch because it may switch an optical single from any one of four fibers 312 and to any other one of the four fibers 312. The optical switch device 310 includes an array 320 of rotatable reflectors 322 20 and a fixed reflector 324 that is fixed relative to the array 320 of rotatable reflectors 322. Each of the rotatable reflectors 322 corresponds with a separate one of the fibers 312. The rotatable reflectors may be of the type shown in FIG. 7. The optical switch device 310 also includes fiber beam forming units 370 comprised of cylindrical sleeves 376 enclosing optical fiber ends (not shown) and lenses (not shown). A separate fiber beam 25 unit 370 is associated with each one of the fibers 312. An optical signal from any one of the fibers 312 is switched to any other one of the fibers 312 in the following manner. An optical signal from, for example, the (1,1) fiber 312 propagates along the optical pathway 330 between the fiber beam forming unit 370 associated with the (1,1) fiber 312 and the (1,1) rotatable reflector 322. The (1,1) 30 rotatable reflector 322 is rotated such the optical signal is reflected to the fixed reflector 324 along optical pathway 340. The fixed reflector 324 reflects the optical signal along optical pathway 350 to the (1,3) rotatable reflector 322. The (1,3) rotatable reflector 322 13 WO 99/66354 PCT/US99/12550 is rotated such that it reflects the optical signal along optical pathway 334 to fiber beam forming unit 370 associated with the (1,3) fiber 312. Similarly, an optical signal from the (1,2) fiber 312 propagates along optical pathway 332 to the (1,2) rotatable reflector 322, which is rotated so that the optical signal is reflected along optical pathway 342 to 5 the fixed reflector 324. The fixed reflector 324 reflects the optical signal along optical pathway 352 to the (1,4) rotatable reflector 322 which is rotated so that the optical signal is reflected along optical pathway 336 the fiber beam forming unit 370 associated with the (1,4) fiber 312. The optical pathways 330, 332, 334, 336 between the rotatable reflectors 322 and the fiber beam forming units 370 associated with their corresponding 10 fibers 312 are in substantial alignment with axes extending centrally from the corresponding fiber 312. Focused Beam Forming Units As noted above, the embodiments illustrated may include a beam forming unit 15 associated with each fiber input and output for forming optical signals into a beams. Such fiber beam forming units preferably form the optical signals into focused beams as opposed to collimated or other diverging signals. Figs. 9 and 10 illustrate the differences between a collimated signal 510 formed by a collimated forming unit 512 and a focused beam 520 formed by a focused signal 20 forming unit 522. As shown in FIG. 9, a first collimated beam forming unit 512A includes a source, such as an optical fiber end 514, from which an optical signal, such as infrared light, is emitted and a collimating lens 516. Since the optical fiber end 514 is not an infinitesimally small point source, rays of light from different points on the optical fiber end 514, such as rays 518A, 518B, 518C, are incident on the surface of the 25 collimating lens 516 facing the optical fiber end 514. The collimating lens 516 directs the rays 518A, 518B, 518C such that rays from a particular point on the optical fiber end 514 exit the lens 514 in a parallel fashion. As can be seen in FIG. 9, because each of the rays 518A, 518B, 518C exit the lens 514 in a parallel fashion, much of the optical signal will not be incident on the lens 516 of a second fiber beam forming unit 512B to which 30 the optical signal is directed causing much of the optical signal to be lost. Fig. 10 shows a focused beam 520 formed by a first focused beam forming unit 522A. The first focused beam forming unit 522A includes a source, such as an optical 14 WO 99/66354 PCT/US99/12550 fiber end 524, from which an optical signal, such as infrared light, is emitted and a focused lens 526. As with the first collimated beam forming unit 512A, rays of light from different points on the optical fiber end 524, such as rays 528A, 528B, 528C, are incident on the surface of the focused lens 526 facing the optical fiber end 524. Instead 5 of directing the rays 528A, 528B, 528C from each point in a parallel fashion, the focused lens 526 directs the rays 528A, 528B, 528C such that the rays from a particular point on the optical fiber end 524 converge at one point on the surface of the focused lens 526 of the second focused beam forming unit 522B to which the optical signal is directed. Thus, much of the optical signal reaches its intended destination and signal losses are 10 minimized. In Fig. 11 there is shown a symmetrical system of substantially identical focused fiber beam forming units 522A, 522B where the fibers on each side have the same diameter of optical aperture, d, and numerical aperture N.A. Such a symmetrical system is preferred in order to facilitate optimal transmission efficiency of the optical signal 15 between the focused fiber beam forming units 522A, 522B. Generally, optimum optical signal transmission efficiency is achieved when the following three equations are substantially satisfied, given certain practical constraints such as accommodating differing path lengths across the switch interface for different input fiber to output fiber switching combinations: 20 D = 2u – tan (sin-‘ (N.A.)) + d 1/f= 1/v + 1/u d/u D/v D is the effective optical aperture of the focusing lenses 526. The distance between the lens 526 and the optical fiber end 524 of the first focused beam forming unit 522A as 25 well as the distance between the lens 526 and the optical fiber end 524 of the second focused beam forming unit 522B is u. The distance between the lens 526 of the first focused beam forming unit 522A and the lens 526 of the second focused beam forming unit 522B is v. It will be appreciated that the value of v may vary depending on the particular switching combination under consideration and, in this regard, the focusing 30 functionality described herein will be understood as encompassing such variations from true focusing functionality as may be desired to accommodate practical switch designs. NA is the numerical aperture of the optical fiber ends 524, and f is the focal length of the 15 WO 99/66354 PCT/US99/12550 lenses 526. A thin lens approximation is assumed, and it is also assumed that D>>d. Further, if the beam carried in the optical fibers is a Gaussian beam, the effective values of d, D and NA are determined on a l/e 2 irradiance basis. 5 Substantial Alignment In the embodiments described above, it is noted that when the optical signal is directed to the fiber end and/or fiber beam forming unit associated with the fiber end, it will propagate along an optical pathway having an axis that is in substantial alignment with an axis extending centrally from the end of the fiber output and/or lens of the fiber 10 beam forming unit associated with the fiber output and will pass within the effective optical aperture diameter of the beam forming unit. Those skilled in the art will appreciate that it is sufficient to have substantial alignment where the angle, if any, between the axis of the optical pathway and the axis extending from the fiber output and/or lens is substantially smaller than the N.A. of the fiber and the pathway passes 15 through the effective optical aperture diameter of the beam forming unit. This may be better understood by reference to Figs. 12-14. Fig. 12 is a cross sectional view of a fiber 600. The fiber includes a core 602 for carrying optical signals surrounded by cladding 604. In order to efficiently transmit optical signals along the length of the fiber 600, it is desirable to provide a high degree of reflectivity at the 20 core/cladding interface 606, e.g., by forming the core 602 and cladding 604 from materials having differing indices of refraction or otherwise providing a reflective coating. As shown in Fig. 12, the illustrated interface 606 has a critical angle such that optical rays 608 having an angle of incidence less than the critical angle are transmitted through the core 602 and rays 610 having an angle of incidence greater than the critical 25 angle are not transmitted through the core 602. This critical angle defines the «acceptance» angle of the fiber 600, a, the sim of which is desired as the fiber’s numerical aperture. Fig. 13 shows the fiber 600 and lens 612 geometry. As shown, an effective optical aperture diameter, D, of the lens 612 is defined by the optical aperture diameter, 30 d, of the fiber core 602 and the numerical aperture NA. Specifically, as noted above: D = 2u -tan (sin 1 (N.A.)) + d 16 WO 99/66354 PCT/US99/12550 Physically, this means that signals transmitted from the fiber 600 will pass within the area defined by D. Conversely, incoming optical signals that are substantially aligned with the fiber axis before entering the lens and passing within the area defined by D will be substantially accepted by the fiber 600. 5 Referring to Fig. 14, an imaging geometry in accordance with the present invention is shown. For purposes of illustration, a straight (unfolded) optical path connecting first and second fibers is shown and the beam directing units, e.g., mirror arrays, are omitted. As described above, the first beam forming unit 700 preferably images the core 702 of first fiber 704 onto the effective diameter D 2 of second beam 10 directing unit 706. Similarly, the second beam directing unit 706 preferably images the core 708 of second fiber 710 onto the effective diameter D, of the first beam forming unit 700. It will be appreciated that, in the case of an NXN switch, the length of the optical path between the beam forming units, v, may vary somewhat depending upon the particular connection. However, substantial imaging can be achieved for all connections 15 provided that the variation of v from path to path minimized, preferably to less than about 10%. This can be achieved, for example, by increasing the magnitude of v relative to the dimension of the fiber arrays. Where folded optical paths are employed, substantial imaging can be achieved in reasonably compact switches. As shown in Fig. 14, the beam forming unit 700 images the core 702 onto beam forming unit 706, and the beam forming 20 unit 706 images the core 708 onto the beam forming unit 700. This is graphically depicted by the arrows and inverted arrows shown in the Figure. This is accomplished by satisfying the mathematical/geometric relationships set forth above. Such imaging enhances the optical efficiency of the switch. While various embodiments of the present invention have been described in 25 detail, it is apparent that further modifications and adaptations of the invention will occur to those skilled in the art. However, it is expressly understood that such modifications and adaptations are within the spirit and scope of the present invention. 17

Claims (39)

1. An optical switch comprising: a plurality of optical fibers for use in transmitting optical signals; a plurality of beam forming devices each having an optical aperture, each of said 5 beam forming devices being optically associated with a corresponding one of said plurality of optical fibers, said fibers and beam forming devices being configured such that each of said beam forming devices can image an optical aperture of a corresponding one of said fibers onto the optical aperture of another one of said beam forming devices corresponding to another one of said fibers; 10 a plurality of beam directing devices, each of said beam directing devices being optically associated with a corresponding one of said plurality of optical fibers, said beam directing devices being operative to establish an optical connection between a first fiber of said optical fibers and a second of said optical fibers by directing beams from said first fiber to said second fiber and directing beams from said second fiber to said first fiber so 15 as to permit bi-directional communication between said first and second fibers; said beam directing devices further being operative for establishing said connection between said first and second fibers such that, at an optical aperture of each of said first and second fibers, any angle between an axis of a beam entering or exiting a respective one of said first and second fibers and an axis of said respective one of said 20 first and second fibers, is less than a numerical aperture of said respective one of said first and second fibers.

2. An optical switch as set forth in Claim 1, wherein each of said beam directing devices is a mirror rotatable about at least one axis.

3. An optical switch as set forth in Claim 2, wherein said mirror is embedded 25 in a MEM chip.

4. An optical switch as set forth in Claim 1, wherein said plurality of optical fibers is arranged in an array facing a fixed mirror so as to enable interconnection between any pair of said fibers.

5. An optical switch as set forth in Claim 1, wherein said plurality of optical 30 fibers is arranged in first and second arrays so as to enable interconnection between any fiber of said first array and any fiber of said second array. 18 WO 99/66354 PCT/US99/12550

6. An optical switch device for directing optical signals between a first input optical fiber end of a plurality of input optical fiber ends and a plurality of output optical fiber ends, said optical switch device comprising: a plurality of beam directing units, each optically disposed relative to a 5 corresponding one of said plurality of output optical fiber ends for receiving an optical signal transmitted from the first input optical fiber end and directing the optical signal to said corresponding one of said plurality of output fiber ends along an optical pathway having a pathway axis that is in substantial alignment with a fiber axis extending centrally from said corresponding output fiber end. 10

7. The optical switch device of Claim 6, wherein any angle between said pathway axis and said fiber axis is less than a numerical aperture of an output fiber associated with said corresponding output fiber end.

8. The optical switch device of Claim 6, wherein said beam directing unit comprises: 15 first reflective means, associated with the first input fiber end, for receiving the optical signal from the first input fiber end and reflecting the optical signal at an angle determined by the orientation of said first reflective means; and second reflective means, associated with the corresponding one of said output fiber end, for receiving the optical signal reflected by said first reflective means and 20 reflecting the optical signal along an optical pathway having an axis extending between said second reflective means and the corresponding one of said output fiber ends, said second reflective means being oriented such that said axis of said optical pathway is in substantial alignment with said fiber.

9. The optical switch device of Claim 8, wherein said first and second 25 reflective means are mirrors.

10. The optical switch device of Claim 8 wherein said first and second reflective means are positionable in a plurality of orientations.

11. The optical switch device of Claim 8 wherein said first and second reflective means are rotatable about at least one axis of rotation to a plurality of 30 orientations.

12. The optical switch device of Claim 8 further comprising: 19 WO 99/66354 PCT/US99/12550 first beam forming means, disposed between the first input fiber end and said first reflective means, for forming an optical signal emitted from the first input fiber end into a focused beam optical signal targeted on said first reflective means; and second beam forming means, disposed between the corresponding one of said 5 output fiber ends and said second reflective means, for receiving the focused beam optical signal from said second reflective means and focusing the focused beam optical signal onto the corresponding one of said output fiber ends.

13. The optical switch device of Claim 8 further comprising: third reflective means, fixed relative to said first and second reflective means, for 10 receiving the reflected optical signal from said first reflective means and further reflecting the optical signal to said second reflective means.

14. An optical switch device for directing optical signals between a plurality of input and output optical fibers, said optical switch device comprising: reflective means for reflecting an optical signal incident thereon at an angle 15 determined by the orientation of said reflective means; a first array of a plurality of said reflective means; and at least one additional array of a plurality of said reflective means; wherein, an optical signal emitted from a selected input fiber is directed to a selected output fiber when a combination of a selected one of said reflective means of 20 said first array and a selected one of said reflective means of each said additional array are in respective predetermined orientations.

15. The optical switch device of Claim 14 wherein said reflective means are positionable in a plurality of orientations.

16. The optical switch device of Claim 14 wherein said reflective means are 25 rotatable about at least one axis of rotation to a plurality of orientations.

17. The optical switch device of Claim 14 wherein said reflective means are mirrors.

18. The optical switch device of Claim 14 wherein said reflective means include a pair of orthogonal axes of rotation about which said reflective means are 30 rotatable to a plurality of orientations.

19. The optical switch device of Claim 14 wherein said at least one additional array comprises second, third and fourth arrays of a plurality of said reflective means. 20 WO 99/66354 PCT/US99/12550

20. The optical switch device of Claim 19 wherein each said reflective means of said first and third arrays include an axis of rotation about which said reflective means of said first and third arrays are rotatable to a plurality of orientations and each said reflective means of said second and fourth arrays include an axis of rotation about which 5 said reflective means of said second and fourth arrays are rotatable to a plurality of orientations, said axes of rotation of said reflective means of said first and third arrays being orthogonal to said axes of rotation of said second and fourth arrays.

21. The optical switch device of Claim 14 further comprising: beam forming means, associated with each input fiber and disposed between the 10 end of its associated input fiber and said first array, for forming an optical signal emitted from the end of its associated input fiber into a focused beam optical signal targeted on a corresponding one of said reflective means of said first array; and beam forming means, associated with each output fiber and disposed between the end of its associated output fiber and a last one of said at least one additional array, for 15 receiving the focused beam optical signal from one of said reflective means of said last one of said at least one additional array corresponding to its associated output fiber and focusing the focused beam optical signal onto the end of its associated output fiber.

22. An optical switch device for directing optical signals between ends of a plurality of optical fibers, said optical switch device comprising: 20 reflective means for reflecting an optical signal incident thereon at an angle determined by the orientation of said reflective means; an array of a plurality of said reflective means; and additional means for reflecting an optical signal between one of said reflective means of said array to a second one of said reflective means of said array; 25 wherein, when a combination of two of said reflective means of said array are in respective predetermined orientations, an optical signal emitted from an end of one optical fiber is directed to an end of a second optical fiber by said combination.

23. The optical switch device of Claim 22 wherein said reflective means are positionable in a plurality of orientations. 30

24. The optical switch device of Claim 22 wherein said reflective means are rotatable about at least one axis of rotation to a plurality of orientations. 21 WO 99/66354 PCT/US99/12550

25. The optical switch device of Claim 22 wherein said reflective means are mirrors.

26. The optical switch device of Claim 22 wherein said reflective means include a pair of orthogonal axes of rotation about which said reflective means are 5 rotatable to a plurality of orientations.

27. The optical switch device of Claim 22 wherein said additional means are a mirror fixed relative to said array.

28. The optical switch device of Claim 22 further comprising: beam forming means for forming an optical signal into a focused beam associated 10 with each optical fiber and disposed between the end of its associated fiber and said array such that an optical signal emitted from the end of its associated fiber is focused on a corresponding one of said reflective means of said array.

29. An optical switch for directing an optical signal between an first fiber end and a selected second fiber end of a plurality of output fibers, said optical switch 15 comprising: first focusing means, disposed in known spatial relation to the first fiber end, for receiving said optical signal from said input fiber end and forming a focused beam, wherein said focused beam includes rays that converge to create an image of the first fiber on the second focusing means; second focusing means is imaging the end of the second fiber onto the first 20 focusing means; beam directing unit, optically disposed relative to said focusing means for receiving said focused beam, for selectivity directing said focused beam relative to said selected second fiber end so as to optically connect said first fiber end and said selected output fiber end for transmission of said optical signal therebetween. 25

30. The optical switch of Claim 29 further comprising: second focusing means, disposed in known spatial relation to the selected output fiber end, for receiving said focused beam from said beam directing unit and focusing said focused beam onto the selected output fiber end.

31. The optical switch device of Claim 30 wherein said first focusing means 30 is a first lens having a first surface facing the input fiber end and a second surface facing opposite said first surface of said first lens, and said second focusing means is a second 22 WO 99/66354 PCT/US99/12550 lens having a first surface facing the output fiber end and a second surface facing opposite said first surface of said second lens.

32. The optical switch device of Claim 31 wherein with D representing the effective aperture of said first and second lenses, u representing the distance between said 5 first lens and the input fiber end and the distance between said second lens and the output fiber end, v representing the distance between said first and second lenses, NA representing the numerical aperture of the input and output fiber ends, and f representing the focal length of said first and second lenses, the following equations are satisfied: D = 2 u tan (sin-‘ (N.A.)) + d 10 1/f= l/v + l/u d/u =D/v when a thin lens approximation is assumed.

33. The optical switch device of Claim 29 wherein said beam directing unit comprises a first reflector and a second reflector. 15

34. The optical switch device of Claim 33 wherein said reflectors are micro electro mechanical mirrors.

35. The optical switch device of Claim 34 wherein each of said mirrors is rotatable about at least one axis.

36. A method of switching an optical signal between the end of an input fiber 20 and the end of an output fiber, said method comprising: forming the signal emitted from the input fiber end into a focused beam wherein rays of the optical signal emitted from a point on the input fiber end are directed in a convergent manner; directing said focused beam towards the end of the output fiber end such that, 25 prior to reaching the output fiber end, said a central axis of said focused beam is substantially aligned with an axis extending centrally from the output fiber end; and receiving said focused beam on the output fiber end.

37. The method of Claim 36 wherein in said step of forming, a first focused beam forming unit is employed, and in said step of receiving, a second focused beam 30 forming unit is employed, said first and second focused beam forming units being substantially identical and together comprising a symmetrical focused beam unit. 23 WO 99/66354 PCT/US99/12550

38. The method of Claim 36 wherein in said step of directing, the angle between said central axis of said focused beam and the axis extending centrally from the output fiber end is less than a numerical aperture of said output fiber.

39. The method of Claim 36 wherein in said step of directing, at least two 5 reflectors are employed. 24

AU55419/99A
1998-06-05
1999-06-04
Planar array optical switch and method

Ceased

AU760646B2
(en)

Applications Claiming Priority (3)

Application Number
Priority Date
Filing Date
Title

US8807598P

1998-06-05
1998-06-05

US60/088075

1998-06-05

PCT/US1999/012550

WO1999066354A2
(en)

1998-06-05
1999-06-04
Planar array optical switch and method

Publications (2)

Publication Number
Publication Date

AU5541999A
true

AU5541999A
(en)

2000-01-05

AU760646B2

AU760646B2
(en)

2003-05-22

Family
ID=22209266
Family Applications (1)

Application Number
Title
Priority Date
Filing Date

AU55419/99A
Ceased

AU760646B2
(en)

1998-06-05
1999-06-04
Planar array optical switch and method

Country Status (12)

Country
Link

US
(4)

US6466711B1
(en)

EP
(1)

EP1092166A4
(en)

JP
(1)

JP2002518700A
(en)

KR
(1)

KR20010071412A
(en)

CN
(1)

CN1192263C
(en)

AU
(1)

AU760646B2
(en)

BR
(1)

BR9911618A
(en)

CA
(1)

CA2331990A1
(en)

IL
(1)

IL140031A0
(en)

MX
(1)

MXPA00012024A
(en)

RU
(1)

RU2267143C2
(en)

WO
(1)

WO1999066354A2
(en)

Families Citing this family (71)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

EP1092166A4
(en)

*

1998-06-05
2004-09-29
Afn Llc
Planar array optical switch and method

US6694072B1
(en)

1999-07-21
2004-02-17
Armand P. Neukermans
Flexible, modular, compact fiber switch improvements

US6445844B1
(en)

1999-09-15
2002-09-03
Xros, Inc.
Flexible, modular, compact fiber optic switch

US6690885B1
(en)

*

1999-10-07
2004-02-10
Lucent Technologies Inc.
Optical crossconnect using tilting mirror MEMS array

US6618520B2
(en)

*

1999-11-09
2003-09-09
Texas Instruments Incorporated
Micromirror optical switch

US6798992B1
(en)

*

1999-11-10
2004-09-28
Agere Systems Inc.
Method and device for optically crossconnecting optical signals using tilting mirror MEMS with drift monitoring feature

DE60018883T2
(en)

*

1999-11-17
2006-04-13
Lucent Technologies Inc.

Optical cross connection system with micro-electromechanical tilting mirror arrangement

CA2325611C
(en)

1999-12-01
2004-04-20
Lucent Technologies Inc.
An optical cross connect employing a curved optical component

EP1151343A1
(en)

*

1999-12-01
2001-11-07
XROS, Inc., Nortel Networks
Arrangement of multiple 1xn optical switches

CA2300780C
(en)

*

2000-03-15
2007-08-07
Nortel Networks Corporation
Integrated photonic switch

US6330102B1
(en)

*

2000-03-24
2001-12-11
Onix Microsystems
Apparatus and method for 2-dimensional steered-beam NxM optical switch using single-axis mirror arrays and relay optics

US7023604B2
(en)

2000-03-25
2006-04-04
Analog Devices, Inc.
Three dimensional optical switches and beam steering modules

US6738583B1
(en)

*

2000-05-01
2004-05-18
Agilent Technologies, Inc.
Self-aligning infra-red communication link

US7296904B2
(en)

*

2000-05-12
2007-11-20
University Of Southern California
Reflector for laser interrogation of three-dimensional objects

US6585383B2
(en)

2000-05-18
2003-07-01
Calient Networks, Inc.
Micromachined apparatus for improved reflection of light

US6516109B2
(en)

*

2000-05-30
2003-02-04
Siwave, Inc.
Low insertion loss non-blocking optical switch

US6728016B1
(en)

2000-06-05
2004-04-27
Calient Networks, Inc.
Safe procedure for moving mirrors in an optical cross-connect switch

US6587611B1
(en)

2000-06-06
2003-07-01
Calient Networks, Inc.
Maintaining path integrity in an optical switch

US6363182B2
(en)

*

2000-07-31
2002-03-26
James D. Mills
Optical switch for reciprocal traffic

US6643425B1
(en)

2000-08-17
2003-11-04
Calient Networks, Inc.
Optical switch having switch mirror arrays controlled by scanning beams

US6775043B1
(en)

2000-08-21
2004-08-10
Blue Sky Research
Reflector assemblies for optical cross-connect switches and switches fabricated therefrom

US6418247B1
(en)

*

2000-09-08
2002-07-09
Harris Corporation
Fiber optic switch and associated methods

KR100805969B1
(en)

*

2000-09-29
2008-02-25
텍사스 인스트루먼츠 인코포레이티드
Optical add drop multiplexer

US6816640B2
(en)

*

2000-09-29
2004-11-09
Texas Instruments Incorporated
Optical add drop multiplexer

US6633694B2
(en)

*

2000-09-29
2003-10-14
Texas Instruments Incorporated
Micromirror optical switch

JP2002214546A
(en)

*

2000-11-15
2002-07-31
Oki Electric Ind Co Ltd
Optical switch

CA2327862A1
(en)

2000-11-20
2002-05-20
Thomas Ducellier
Optical switch

US6560000B2
(en)

2000-11-20
2003-05-06
Jds Uniphase Inc.
Wavelength-dependent optical signal processing using an angle-to-offset module

US7039267B2
(en)

2000-11-20
2006-05-02
Jds Uniphase Inc.
Optical switch

US6600849B2
(en)

2000-11-20
2003-07-29
Jds Uniphase Inc.
Control system for optical cross-connect switches

CA2326362A1
(en)

2000-11-20
2002-05-20
Thomas Ducellier
Optical switch

US7212745B2
(en)

*

2000-11-30
2007-05-01
Matsushita Electric Industrial Co., Ltd.
Optical transmission system

US6873755B2
(en)

*

2000-12-20
2005-03-29
Pts Corporation
Wavelength router with staggered input/output fibers

US6690849B1
(en)

2001-01-05
2004-02-10
Tellium, Inc.
Optical switch having MEMS array with reduced optical loss

US6628857B1
(en)

*

2001-01-11
2003-09-30
Tellium, Inc.
Optical switch with an array of offset angled micro-mirrors

US6480645B1
(en)

2001-01-30
2002-11-12
Tellium, Inc.
Sidewall electrodes for electrostatic actuation and capacitive sensing

JP4023584B2
(en)

*

2001-03-02
2007-12-19
富士通株式会社

Light switch

US6792177B2
(en)

*

2001-03-12
2004-09-14
Calient Networks, Inc.
Optical switch with internal monitoring

JP2002277763A
(en)

*

2001-03-22
2002-09-25
Mitsubishi Electric Corp
Space spreading type optical switch

US6882766B1
(en)

2001-06-06
2005-04-19
Calient Networks, Inc.
Optical switch fabric with redundancy

US7110633B1
(en)

2001-08-13
2006-09-19
Calient Networks, Inc.
Method and apparatus to provide alternative paths for optical protection path switch arrays

US6640023B2
(en)

2001-09-27
2003-10-28
Memx, Inc.
Single chip optical cross connect

US6813057B2
(en)

2001-09-27
2004-11-02
Memx, Inc.
Configurations for an optical crossconnect switch

US6794793B2
(en)

2001-09-27
2004-09-21
Memx, Inc.
Microelectromechnical system for tilting a platform

US6738539B2
(en)

2001-10-03
2004-05-18
Continuum Photonics
Beam-steering optical switching apparatus

US6636656B2
(en)

*

2001-10-24
2003-10-21
Transparent Networks, Inc.
System architecture of optical switching fabric

US20030081883A1
(en)

*

2001-10-26
2003-05-01
Corning, Inc.
Checker-board optical cross-connect

US6900915B2
(en)

2001-11-14
2005-05-31
Ricoh Company, Ltd.
Light deflecting method and apparatus efficiently using a floating mirror

US6944365B2
(en)

*

2002-01-03
2005-09-13
Memx, Inc.
Off axis optical signal redirection architectures

US6959126B1
(en)

2002-02-08
2005-10-25
Calient Networks
Multipurpose testing system for optical cross connect devices

US6788842B1
(en)

2002-03-05
2004-09-07
Calient Networks
Method and apparatus for internal monitoring and control of reflectors in an optical switch

US7379668B2
(en)

*

2002-04-02
2008-05-27
Calient Networks, Inc.
Optical amplification in photonic switched crossconnect systems

JP2004077854A
(en)

*

2002-08-20
2004-03-11
Fujitsu Ltd
Light switch and method for using the same

US6961259B2
(en)

*

2003-01-23
2005-11-01
Micron Technology, Inc.
Apparatus and methods for optically-coupled memory systems

US7027219B2
(en)

*

2003-02-03
2006-04-11
Gatton Averell S
Method and system for mirror telescope configuration

US6900922B2
(en)

*

2003-02-24
2005-05-31
Exajoule, Llc
Multi-tilt micromirror systems with concealed hinge structures

GB2403022C
(en)

*

2003-06-19
2008-10-30
Polatis Ltd
Flexible increase to optical switch capacity

US7403719B2
(en)

*

2003-06-30
2008-07-22
Texas Instruments Incorporated
Feedback control for free-space optical systems

JP2005031388A
(en)

2003-07-14
2005-02-03
Hitachi Ltd
Beam direction module and optical switch using the same

US7263252B2
(en)

*

2003-07-28
2007-08-28
Olympus Corporation
Optical switch and method of controlling optical switch

US7369721B2
(en)

*

2003-09-26
2008-05-06
Mbda Uk Limited
Optical imaging system with optical delay lines

WO2006008483A2
(en)

*

2004-07-15
2006-01-26
Polatis Ltd
An optical switch

GB0518732D0
(en)

*

2005-09-14
2005-10-19
Polatis Ltd
Latching switch improvements

US20100040325A1
(en)

*

2007-03-26
2010-02-18
Trex Enterprises Corp.
Low-cost multimode optical fiber switch

CN102156330B
(en)

*

2010-08-12
2013-01-30
华为技术有限公司
Optical switch and method for implementing optical switch

WO2016070362A1
(en)

2014-11-05
2016-05-12
华为技术有限公司
Optical switch for micromotor system, and exchanging node

KR101911351B1
(en)

*

2017-01-11
2018-10-25
재단법인 오송첨단의료산업진흥재단
Ellipsoidal reflector and optical signal transmission module having the same

CN107561718A
(en)

*

2017-10-26
2018-01-09
广东工业大学
A kind of digital fiber bundling device and the method that dynamic mask is obtained using optical-fiber bundling

FR3094501B1
(en)

*

2019-03-29
2021-04-02
Oledcomm

Lighting and communication system comprising a transmitter and a receiver of modulated light signals

CN114200590B
(en)

*

2021-12-09
2023-06-27
武汉光迅科技股份有限公司
Two-dimensional MEMS optical switch Hitless switching control method and device

CN115016080B
(en)

*

2022-08-09
2022-11-01
武汉乾希科技有限公司
Optical transmission assembly and method for assembling optical transmission assembly

Family Cites Families (98)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US2982859A
(en)

1959-02-04
1961-05-02
Engelhard Hanovia Inc
Light communication alinement system

US3349174A
(en)

1964-02-03
1967-10-24
Raytheon Co
Beam scanning device

GB1160546A
(en)

1965-07-08
1969-08-06
Spiro John Catravas
Selector Switching Systems Utilising Optical Interconnecting Paths Occupying a Common Space

DE1255541B
(en)

1965-12-15
1967-11-30
Nippon Electric Co

Optical communication arrangement

US3649105A
(en)

1968-02-21
1972-03-14
North American Rockwell
Optical shutter

US4003655A
(en)

1975-04-17
1977-01-18
The United States Of America As Represented By The Secretary Of The Army
Hybrid silicon avalanche quadrant detector

US4198116A
(en)

1975-04-30
1980-04-15
Thomson-Csf
Electro-optical switch and modulator

US3990780A
(en)

1975-08-22
1976-11-09
Gte Laboratories Incorporated
Optical switch

JPS53137631A
(en)

1977-05-07
1978-12-01
Canon Inc
Terminal unit for information processing

FR2411426A1
(en)

1977-12-09
1979-07-06
Thomson Csf

ELECTRICALLY CONTROLLED OPTICAL BIFURCATION AND ITS APPLICATION TO FIBER OPTIC TRANSMISSION DEVICES

US4304460A
(en)

*

1978-03-10
1981-12-08
Matsushita Electric Industrial Co., Ltd.
Optical switching device

US4234145A
(en)

1978-05-17
1980-11-18
Northrop Corporation
Radiant energy quadrant detection device

US4208094A
(en)

1978-10-02
1980-06-17
Bell Telephone Laboratories, Incorporated
Optical switch

JPS5566154A
(en)

1978-11-13
1980-05-19
Hitachi Denshi Ltd
Optical communication system

JPS5574503A
(en)

1978-11-29
1980-06-05
Nec Corp
Mechanical photo switch

JPS55105210A
(en)

1979-02-08
1980-08-12
Nec Corp
Photo switch element

FR2458195B1
(en)

1979-05-30
1986-02-28
Materiel Telephonique

VERY LARGE NUMBER OF CHANNELS OPTICAL SWITCH

JPS55159402A
(en)

*

1979-05-31
1980-12-11
Fujitsu Ltd
Full mirror type channel-connecting photo switch having photo detector

US4993796A
(en)

1979-08-14
1991-02-19
Kaptron, Inc.
Fiber optics communication modules

US4249814A
(en)

1979-10-01
1981-02-10
Iowa State University Research Foundation, Inc.
Frustrated total internal reflection camera shutter

US4303302A
(en)

1979-10-30
1981-12-01
Gte Laboratories Incorporated
Piezoelectric optical switch

US4796263A
(en)

1979-12-21
1989-01-03
Westinghouse Electric Corp.
FTIR optical manifold and wavelength agile laser system

US4603975A
(en)

1980-03-17
1986-08-05
Hughes Aircraft Company
Apparatus and method for nighttime and low visibility alignment of communicators

US4432599A
(en)

*

1981-03-27
1984-02-21
Sperry Corporation
Fiber optic differential sensor

US4431258A
(en)

1981-12-15
1984-02-14
Gte Laboratories Incorporated
Optical fiber transmission system and dichroic beam splitter therefor

DE3206919A1
(en)

1982-02-26
1983-09-15
Philips Patentverwaltung Gmbh, 2000 Hamburg

DEVICE FOR OPTICALLY DISCONNECTING AND CONNECTING LIGHT GUIDES

FR2523735A1
(en)

*

1982-03-22
1983-09-23
Labo Electronique Physique
High capacity fibre optic channel switching device – has orientation controllable deflectors for emitter-receiver fibre pair selection

DE3213076A1
(en)

1982-04-07
1983-10-20
Max Planck Gesellschaft zur Förderung der Wissenschaften e.V., 3400 Göttingen

SECONDARY MIRROR TILTING DEVICE FOR A MIRROR TELESCOPE

US4574191A
(en)

1982-12-30
1986-03-04
The United States Of America As Represented By The Secretary Of The Army
Wide field-of-view laser spot tracker

US4470662A
(en)

1983-04-07
1984-09-11
Mid-West Instrument
Rotary optic switch

FR2548795B1
(en)

1983-07-04
1986-11-21
Thomson Csf

OPTICAL SWITCHING DEVICE WITH FLUID DISPLACEMENT AND DEVICE FOR COMPOSING A POINT LINE

US4644160A
(en)

1983-12-14
1987-02-17
Hitachi, Ltd.
System for holding plural light beams in predetermined relative positions

US4626066A
(en)

1983-12-30
1986-12-02
At&T Bell Laboratories
Optical coupling device utilizing a mirror and cantilevered arm

JPS60185918A
(en)

1984-03-05
1985-09-21
Canon Inc
Optical modulating method

FR2569864B1
(en)

1984-09-04
1987-01-30
Commissariat Energie Atomique

OPTICAL FIBER LIGHT EMITTING AND DISTRIBUTION EQUIPMENT, PARTICULARLY FOR ONLINE SPECTROPHOTOMETER CONTROL USING A DOUBLE BEAM SPECTROPHOTOMETER

US4614868A
(en)

1984-10-12
1986-09-30
Caterpillar Industrial Inc.
Fiber optic seam tracking apparatus

GB2171793B
(en)

1985-02-27
1989-06-14
Drottninghamnsvagen Bergstrom
Electromagnetic radiation circuit element

EP0220455A1
(en)

*

1985-09-24
1987-05-06
Siemens Aktiengesellschaft
Arrangement for coupling a laser diode to a monomode waveguide

DE3538898A1
(en)

1985-11-02
1987-05-07
Zeiss Carl Fa

ELECTRO-MAGNETIC DRIVING SWING MIRROR

US4789215A
(en)

1986-04-18
1988-12-06
Northern Telecom Limited
Fiber optic switch with prism mounted for reciprocal and rotational movement

US4823402A
(en)

1986-04-21
1989-04-18
Trw Inc.
Agile optical beam steering system

US4838631A
(en)

1986-12-22
1989-06-13
General Electric Company
Laser beam directing system

US4838637A
(en)

1987-05-04
1989-06-13
Unisys Corporation
Integrated solid state non-volatile fiber optic switchboard

US5028104A
(en)

1987-05-21
1991-07-02
Kaptron, Inc.
Fiber optics bypass switch

US4859012A
(en)

1987-08-14
1989-08-22
Texas Instruments Incorporated
Optical interconnection networks

JPH0192233A
(en)

1987-10-02
1989-04-11
Teijin Ltd
Resin impregnated sheet

JPH0830787B2
(en)

*

1987-10-16
1996-03-27
日本電信電話株式会社

Fiber optic connector

US4790621A
(en)

1987-12-07
1988-12-13
Gte Products Corporation
Fiber optic switch

GB8800600D0
(en)

1988-01-12
1988-02-10
Univ Manchester
Increasing efficiency of animal performance

JP2576562B2
(en)

1988-01-28
1997-01-29
ソニー株式会社

Optical space transmission equipment

JPH01226228A
(en)

1988-03-04
1989-09-08
Sony Corp
Optical space transmission equipment

GB8816277D0
(en)

1988-07-08
1988-08-10
Univ London
Optical transmission arrangement

EP0367407A3
(en)

1988-10-14
1990-06-13
British Aerospace Public Limited Company
Process and apparatus for controlling alignment of a transmit laser beam of a coherent detection optical communications transmitter/receiver terminal

US4927225A
(en)

1989-05-30
1990-05-22
Finisar Corporation
2×2 Optical bypass switch

US5005934A
(en)

1989-07-11
1991-04-09
Galileo Electro-Optics Corporation
Fiber optics channel selection device

US4932745A
(en)

1989-07-25
1990-06-12
At&T Bell Laboratories
Radiation switching arrangement with moving deflecting element

US5150245A
(en)

1989-10-18
1992-09-22
International Business Machines Corporation
Multiprocessor computer with optical data switch

US5205104A
(en)

*

1989-11-10
1993-04-27
Ishida Scales Mfg. Co., Ltd.
Devices for supplying and transporting film for packaging apparatus

NZ236008A
(en)

*

1989-11-10
1992-12-23
Ishida Scale Mfg Co Ltd
Packaging apparatus has film roll support and film transporting device that are width adjustable

US5037173A
(en)

*

1989-11-22
1991-08-06
Texas Instruments Incorporated
Optical interconnection network

US5031987A
(en)

1990-01-02
1991-07-16
Sundstrand Data Control, Inc.
Fiber optic thermal switch utilizing frustrated total internal reflection readout

US4988157A
(en)

*

1990-03-08
1991-01-29
Bell Communications Research, Inc.
Optical switch using bubbles

DE69114692T2
(en)

1991-03-25
1996-06-20
Ibm

Fiber optic switch with optical remote supply.

JP2617054B2
(en)

1991-10-18
1997-06-04
日本電信電話株式会社

Optical connection module

US5204922A
(en)

1991-10-22
1993-04-20
Puritan-Bennett Corporation
Optical signal channel selector

US5627669A
(en)

1991-11-13
1997-05-06
Canon Kabushiki Kaisha
Optical transmitter-receiver

US5199088A
(en)

1991-12-31
1993-03-30
Texas Instruments Incorporated
Fiber optic switch with spatial light modulator device

US5221987A
(en)

1992-04-10
1993-06-22
Laughlin Richard H
FTIR modulator

US5208880A
(en)

1992-04-30
1993-05-04
General Electric Company
Microdynamical fiber-optic switch and method of switching using same

US5255332A
(en)

*

1992-07-16
1993-10-19
Sdl, Inc.
NxN Optical crossbar switch matrix

US5353164A
(en)

*

1992-10-30
1994-10-04
At&T Bell Laboratories
Objective lens for a free-space photonic switching system

US5291324A
(en)

1992-11-24
1994-03-01
At&T Bell Laboratories
Comparison apparatus with freespace optical interconnections between optoelectronic integrated circuits

US5317659A
(en)

1993-02-09
1994-05-31
Dicon Fiberoptics
Conical fiberoptic switch

US5453827A
(en)

1993-02-24
1995-09-26
Dicon Fiberoptics
Fiberoptic in-line filter and technique for measuring the transmission quality of an optical fiber through the use of a fiberoptic in-line filter

US5436986A
(en)

1993-03-09
1995-07-25
Tsai; Jian-Hung
Apparatus for switching optical signals among optical fibers and method

US5420946A
(en)

1993-03-09
1995-05-30
Tsai; Jian-Hung
Multiple channel optical coupling switch

US5624669A
(en)

*

1993-03-31
1997-04-29
Tri-Point Medical Corporation
Method of hemostatic sealing of blood vessels and internal organs

US5375132A
(en)

*

1993-05-05
1994-12-20
Coherent, Inc.
Solid state laser with interleaved output

US5440654A
(en)

*

1993-12-30
1995-08-08
Raytheon Company
Fiber optic switching system

US5444801A
(en)

*

1994-05-27
1995-08-22
Laughlin; Richard H.
Apparatus for switching optical signals and method of operation

US5546484A
(en)

1994-10-14
1996-08-13
Kaptron, Inc.
Fiber optic switch using polished-type directional coupler

US5594820A
(en)

1995-02-08
1997-01-14
Jds Fitel Inc.
Opto-mechanical device having optical element movable by twin flexures

US5524153A
(en)

1995-02-10
1996-06-04
Astarte Fiber Networks, Inc.
Optical fiber switching system and method using same

CA2156029C
(en)

1995-08-14
2000-02-29
John O. Smiley
Optical switching device

US5661591A
(en)

*

1995-09-29
1997-08-26
Texas Instruments Incorporated
Optical switch having an analog beam for steering light

US5548669A
(en)

*

1995-10-11
1996-08-20
Wireless Control Systems
Optical fiber light cone switch

US5671304A
(en)

1995-12-21
1997-09-23
Universite Laval
Two-dimensional optoelectronic tune-switch

US5956441A
(en)

*

1996-06-14
1999-09-21
Lucent Technologies, Inc.
Multiple port optical component such as an isolater or the like

US6097859A
(en)

*

1998-02-12
2000-08-01
The Regents Of The University Of California
Multi-wavelength cross-connect optical switch

US5960132A
(en)

*

1997-09-09
1999-09-28
At&T Corp.
Fiber-optic free-space micromachined matrix switches

US6031946A
(en)

*

1998-04-16
2000-02-29
Lucent Technologies Inc.
Moving mirror switch

US6320993B1
(en)

*

1998-06-05
2001-11-20
Astarte Fiber Networks, Inc.
Optical switch pathway configuration using control signals

EP1092166A4
(en)

*

1998-06-05
2004-09-29
Afn Llc
Planar array optical switch and method

US6430332B1
(en)

*

1998-06-05
2002-08-06
Fiber, Llc
Optical switching apparatus

WO2000039626A1
(en)

*

1998-12-31
2000-07-06
Optical Coating Laboratory, Inc.
Wavelength selective optical switch

US7245647B2
(en)

*

1999-10-28
2007-07-17
Ricoh Company, Ltd.
Surface-emission laser diode operable in the wavelength band of 1.1-1.7mum and optical telecommunication system using such a laser diode

US6763160B2
(en)

*

2001-04-26
2004-07-13
Creo Srl
Optical cross connect switch having improved alignment control system

US6941073B2
(en)

*

2002-07-23
2005-09-06
Optical Research Associates
East-west separable ROADM

1999

1999-06-04
EP
EP99941946A
patent/EP1092166A4/en
not_active
Withdrawn

1999-06-04
IL
IL14003199A
patent/IL140031A0/en
not_active
IP Right Cessation

1999-06-04
CN
CNB998080373A
patent/CN1192263C/en
not_active
Expired – Fee Related

1999-06-04
WO
PCT/US1999/012550
patent/WO1999066354A2/en
not_active
Application Discontinuation

1999-06-04
AU
AU55419/99A
patent/AU760646B2/en
not_active
Ceased

1999-06-04
JP
JP2000555118A
patent/JP2002518700A/en
active
Pending

1999-06-04
MX
MXPA00012024A
patent/MXPA00012024A/en
not_active
Application Discontinuation

1999-06-04
CA
CA002331990A
patent/CA2331990A1/en
not_active
Abandoned

1999-06-04
US
US09/326,122
patent/US6466711B1/en
not_active
Expired – Lifetime

1999-06-04
BR
BR9911618-9A
patent/BR9911618A/en
not_active
Application Discontinuation

1999-06-04
KR
KR1020007013782A
patent/KR20010071412A/en
not_active
Application Discontinuation

1999-06-04
RU
RU2001101435/28A
patent/RU2267143C2/en
not_active
IP Right Cessation

2002

2002-08-15
US
US10/222,750
patent/US6754409B2/en
not_active
Expired – Lifetime

2004

2004-02-18
US
US10/781,042
patent/US7054520B2/en
not_active
Expired – Fee Related

2006

2006-05-26
US
US11/420,698
patent/US7483602B2/en
not_active
Expired – Fee Related

Also Published As

Publication number
Publication date

KR20010071412A
(en)

2001-07-28

US6466711B1
(en)

2002-10-15

EP1092166A4
(en)

2004-09-29

WO1999066354A3
(en)

2000-06-15

US20030142900A1
(en)

2003-07-31

CN1307690A
(en)

2001-08-08

US20070053630A1
(en)

2007-03-08

CA2331990A1
(en)

1999-12-23

BR9911618A
(en)

2001-03-06

WO1999066354A2
(en)

1999-12-23

IL140031A0
(en)

2002-02-10

EP1092166A2
(en)

2001-04-18

MXPA00012024A
(en)

2003-04-14

US7054520B2
(en)

2006-05-30

RU2267143C2
(en)

2005-12-27

US7483602B2
(en)

2009-01-27

JP2002518700A
(en)

2002-06-25

CN1192263C
(en)

2005-03-09

US20060013526A1
(en)

2006-01-19

AU760646B2
(en)

2003-05-22

US6754409B2
(en)

2004-06-22

Similar Documents

Publication
Publication Date
Title

US6466711B1
(en)

2002-10-15

Planar array optical switch and method

US5037173A
(en)

1991-08-06

Optical interconnection network

US4856863A
(en)

1989-08-15

Optical fiber interconnection network including spatial light modulator

US6668108B1
(en)

2003-12-23

Optical cross-connect switch with integrated optical signal tap

US6002818A
(en)

1999-12-14

Free-space optical signal switch arrangement

US5943454A
(en)

1999-08-24

Freespace optical bypass-exchange switch

US6487334B2
(en)

2002-11-26

Optical switch

JPH05341213A
(en)

1993-12-24

Optical fiber switch

RU2001101435A
(en)

2003-03-20

OPTICAL SWITCH (OPTIONS), OPTICAL SWITCHING DEVICE (OPTIONS) AND METHOD OF OPTICAL SIGNAL SWITCHING

US6483961B1
(en)

2002-11-19

Dual refraction index collimator for an optical switch

US6687428B2
(en)

2004-02-03

Optical switch

EP1271200B1
(en)

2003-12-10

Imaging technique and optical switch using optical MEMS devices

TW538605B
(en)

2003-06-21

Optical serial link

US6836585B2
(en)

2004-12-28

Photonic switch

US7057716B2
(en)

2006-06-06

White cell antenna beamformers

US6768838B2
(en)

2004-07-27

Optical module

US20020061161A1
(en)

2002-05-23

Optical switch

CN111290084A
(en)

2020-06-16

Multicast switching optical switch

US7187820B1
(en)

2007-03-06

Optical time delay system

CA2363625A1
(en)

2002-05-20

Optical switch

WO2002021180A1
(en)

2002-03-14

Optical switch

Legal Events

Date
Code
Title
Description

2002-03-21
DA3
Amendments made section 104

Free format text:
THE NATURE OF THE AMENDMENT IS: AMEND THE DATE OF THE PRIORITY NUMBER TO 19980605

2002-11-07
DA3
Amendments made section 104

Free format text:
THE NATURE OF THE AMENDMENT IS: AMEND INVENTORS TO INCLUDE DAVID KROZIER AND LEO PLOUFFE

2002-12-05
PC1
Assignment before grant (sect. 113)

Owner name:
AFN,LLC

Free format text:
THE FORMER OWNER WAS: ASTARTE FIBER NETWORKS, INC.

2003-09-25
FGA
Letters patent sealed or granted (standard patent)

Download PDF in English

None