FIELD OF INVENTION
[0001] Embodiments of the invention relate to optical switching systems employing angle multiplexing optics.
BACKGROUND
[0002] With the substantial growth in demand for internet bandwidth, internet traffic requirements have become quite unpredictable. In adapting to this challenge, many networks have evolved to use reconfigurable optical add drop modules (ROADM) at nodes in ring and mesh networks. These networks require the use of wavelength switch systems (WSS). Traffic from point A to point B can be routed dynamically through the use of these networks. To enable routing flexibility, these systems employ many usable wavelengths and channels. When needed, a new channel can be deployed in response to an increased bandwidth requirement, or alternatively a channel can be dropped in response to congestion or disruption of part of the network. The evolution of WSS in response to these growing needs involve two basic architectures: colored WSS and colorless WSS.
[0003] The colored WSS will switch a specific wavelength to an associated output fiber. The colored WSS was developed using arrayed waveguide gratings (AWG) as a wavelength multiplexer/de-multiplexer element. The drawback of the colored WSS is that it fails to provide flexibility because fixed or specific wavelengths are needed in order for the switching process to occur, even though tunable lasers are widely available. The wavelength is fixed due to the physical association between the wavelength and a particular output fiber. This limits the ability of a colored WSS to act as an add/drop module because fixed or specified wavelengths are necessary in order to perform the add/drop functions. Using a colored WSS creates an inflexible ROADM and network. The wavelength provisions or routing determinations are made when the WSS is installed, which is a manual rather than dynamic operation.
[0004] The colorless WSS, on the other hand, provides the freedom of choosing any wavelength transmission dynamically, provided that tunable lasers are connected to the WSS. However, each tunable laser can only transmit data via one channel of the WSS. If more wavelengths are needed from a node, more tunable lasers will need to be connected to the WSS. In order to connect more tunable lasers to the WSS, more WSS ports are needed. For this reason, it is desirable to have a WSS with a higher port count, or an optical architecture configured to transmit a greater number of multi-channel optical signals using the existing number of ports.
[0005] There is a need in the art of optical switching for an optical switch architecture that can increase the flexibility of a wavelength switch system while retaining the majority of its design aspects.
[0006] It is within this context that embodiments of the present invention arise.
[0007] US7756368B2 discloses switching optical signals containing a plurality of spectral channels characterized by a predetermined channel spacing. A selected beam deflector array may be selected from among a plurality of available beam deflector arrays configured to accommodate spectral channels of different channel spacings. The selected beam deflector array is configured to accommodate spectral channels of the predetermined channel spacing. The spectral channels are selectively optically coupled to the selected beam deflector array, which selectively optically couples the spectral channels between one or more input ports and one or more output ports.
[0008] US2009304328A1 discloses an optical system comprising two or more optical switches co-packaged together comprising discrete sets of input fiber ports (N per set) and an output fiber port (1 per set), and wherein lambdan from said set of multiple input fiber ports (N) is focused on lambdan mirror via the use of shared free space optics, wherein at least a first array of MEMS mirrors is utilized to select and switch selected wavelengths from the first set of input fiber ports (N) to an output fiber port of the same set, and wherein at least a second array of MEMS mirrors using and sharing the same free space optics is utilized to select individual wavelengths or spectral components from its input fiber ports to send to its output fiber port for optical power or other monitoring purposes, thus, enabling an Nx1, or alternatively a 1xN switch capable of internal feedback monitoring.
[0009] US2007217735A1 discloses an optical switch with a compact form factor, including a multiple-fiber collimator and an angle tuning element for deflecting an optical beam from an input fiber into one of at least two output fibers. The angle tuning element may be provided between a pair of coaxially-aligned collimators, one of which is the multiple-fiber collimator. Alternatively, the angle tuning element may be provided between the multiple-fiber collimator and a reflective surface, so that only one collimator is required and the optical switch may be designed to have its input and output ports on the same side.
SUMMARY
[0010] The present disclosure provides a system as detailed in claim 1. Advantageous features are provided in dependent claims.
BRIEF DESCRIPTION OF THE DRAWINGS
[0011]
FIG. 1A is a top-view schematic diagram illustrating an example of a wavelength switch system according to the prior art.
FIG. 1B is a cross-sectional view schematic diagram illustrating an example of a wavelength switch system according to the prior art
FIG. 2A is a schematic diagram illustrating a basic foundation of optical design.
FIG. 2B is a schematic diagram illustrating another basic foundation of optical design.
FIG. 3A is a top-view schematic diagram illustrating an example of a wavelength switch system employing angle-multiplexing according to an embodiment of the present invention.
FIG. 3B is a cross-sectional view schematic diagram illustrating an example of a wavelength switch system employing angle-multiplexing according to an embodiment of the present invention.
FIG. 4A is a side-view schematic diagram illustrating an input port configured for angle-multiplexing according to an embodiment of the present invention.
FIG. 4B is an axial view schematic diagram illustrating an input port configured for angle-multiplexing according to an embodiment of the present invention.
FIG. 4C is a side-view schematic diagram illustrating an array of ports configured for angle-multiplexing according to an embodiment of the present invention.
FIG. 4D is an axial view schematic diagram illustrating an array of ports configured for angle-multiplexing according to an embodiment of the present invention.
FIG. 5A is a top-view schematic diagram illustrating a wavelength switch system employing angle-multiplexing and angle exchange according to an embodiment of the present invention.
FIG. 5B is a cross-sectional view schematic diagram illustrating a wavelength switch system employing angle-multiplexing and angle exchange according to an embodiment of the present invention.
FIG. 5C is a cross-sectional view schematic diagram illustrating a wavelength switch system employing angle-multiplexing and angle exchange according to another embodiment of the present invention.
FIG. 6A is a top-view schematic diagram illustrating a fiber switch employing angle-multiplexing and angle exchange according to an embodiment of the present invention
FIG. 6B is a cross-sectional view schematic diagram illustrating a fiber switch employing angle-multiplexing and angle exchange according to an embodiment of the present invention.
DESCRIPTION OF THE SPECIFIC EMBODIMENTS
[0012] Embodiments of the present invention utilize an optical architecture that can increase the flexibility of a wavelength switch system while retaining the majority of its design aspects.
INTRODUCTION
[0013] To illustrate the advantages of the inventive wavelength selective switch (WSS) architecture, it is useful to understand the details of a conventional WSS. FIG. 1A-B illustrate an example of a wavelength switch system (WSS) according to the prior art. FIG. 1A illustrates a top-view of the WSS, while FIG. 1B illustrates a cross-sectional view of the WSS. The WSS
100 includes a fiber collimator array
103, a set of relay optics
105, a wavelength separator
107, focusing optics
109, and an array of channel deflective elements
111. The WSS
100 is configured to receive one or more multi-channel optical signals
101 and direct those constituent channels to their respective output ports
106. Each multi-channel optical signal
101 is produced by multiplexing various wavelengths into a single high-speed signal.
[0014] The fiber collimator array
103 is comprised of multiple input ports
104 and output ports
106. Each input port
104 is configured to receive a single multi-channel optical signal
101 and direct that multi-channel optical signal
101 towards a set of relay optics
105. For purposes of illustration, only a single multi-channel optical signal
101 will pass through the WSS
101, but it is important to note that a WSS
100 may be configured to redirect several multi-channel optical signals simultaneously depending on the number of input and output ports available.
[0015] The relay optics
105 are configured to convert the multi-channel optical signal
101 into a spectral beam and direct that spectral beam towards a wavelength separator
107. The relay optics
105 may be implemented using an anamorphic beam expander. The wavelength separator
107 is configured to then separate the spectral beam corresponding to the multi-channel optical signal
101 into its constituent spectral channels (i.e., wavelengths), and pass those spectral channels towards a set of focusing optics
109. By way of example, and not by way of limitation, the wavelength separator
107 may be realized with an interference filter, polarizing filter, arrayed waveguide grating, prism, etc.
[0016] The focusing optics
109 may be configured to receive the individual spectral channels and direct them towards the array of channel deflective elements
111. Each spectral channel will be directed towards a corresponding channel deflective element
113 depending on the configuration of the WSS
100. Depending on the nature of the switching involved, each channel deflective element
113 in the array
111 may be positioned to direct different spectral channels towards different output ports
106. It is important to note that it is possible to direct two different spectral channels to the same output port
106 if their deflective elements
113 are set to perform in that manner. The channel deflective elements
113 may be realized with microelectromechanical system (MEMS) mirrors, bi-stable liquid crystals, UV curable optical mediums, photorefractive holographic gratings, etc.
[0017] It is noted that the number of channels in a switch of the type shown in FIGs. 1A-1B depends on the number of ports in the collimator array
103. As used herein the term "port" refers to an optical path configured to couple optical signals into or out of an optical switch. In a WSS of conventional architecture, such as that depicted in FIGs. 1A-1B, there is one port, e.g., one optical path, per collimator. Increasing the number of ports in a switch of the type shown in FIGs. 1A-1B therefore requires increasing the number of collimators in the array. This, in turn requires an increase in the size of the collimator array
103, relay optics
105, the wavelength separator
107 and the angular range of the deflective elements
111.
[0018] Before describing any embodiments of the present invention, some basic foundations of optical design must be laid. As illustrated in FIG. 2, between two focal points a lens
203 is said to perform a Fourier transform between the spaces of angle and position at the front and back focal planes. To better illustrate this concept, please refer to FIG. 2A and B. In FIG. 2A, two parallel rays coming from the left side of the lens
203 will pass through the same point at the focal plane
201' on the right side of the lens. Similarly, in FIG. 2B, two rays coming from the same point at the focal plane
201 on the left side of the lens will propagate in the same direction on the right side of the lens regardless of their initial angular direction.
[0019] Thus, in order to perform optical switching, a given optical design has to match its optical components with its associated space. In FIGs. 1A-1B, the multi-channel optical signal is dispersed into constituent channels (i.e., wavelengths) of different angles by the wavelength separator. The channels will thus meet the focusing optics at different positions, which will then direct the channels to different deflective elements. The deflective elements will be oriented in different positions to perform angle modulation on the constituent channels, which will alter the positions at which the channels meet the wavelength separator and ultimately determine which output port a given channel is directed towards.
[0020] The cost of optical components including relay optics, gratings, and lenses as well as the costs associated with alignment of the optical system are quite high. As such it is quite desirable to maximize the capacity of the optical setup. The architecture of the switch depicted in FIGs. 1A-1B dictates that in order to increase the number of multi-channel optical signals allowed for switching in a given WSS, the number of ports must be increased. This is because each port may only be configured to receive and transmit a single multi-channel optical signal. Increasing the port count will naturally result in an increase in optical components either vertically or horizontally.
[0021] In the vertical dimension, the size of the fiber collimator array will increase to compensate for the increased port count. The result would be an increase in the height of the overall optical system (e.g., relay optics, wavelength separator, focusing optics), which would significantly affect costs. Additionally, an increase in the vertical dimension would also create a need for an increase in the angular range of the individual channel deflective elements, which may not be easily realized.
[0022] In the horizontal dimension, the collimator array may be expanded to a size of 2xN or MxN in order to compensate for the increased port count. This would require a significant increase in the size as well as the numerical aperture (NA) of the lens system associated with the fiber collimator array, which is quite difficult to implement when attempting to achieve low aberration for low insertion loss. Additionally, the surface area of the relay optics, wavelength separator, and focusing optics would need to be increased, adding to the overall cost and size of the WSS.
ANGLE MULTIPLEXING WSS
[0023] In order to minimize costs associated with increasing the number of multi-channel optical signals being switched, embodiments of the present invention seek to avoid increasing the size of the optical system while increasing the number of ports. Rather than increasing the number of collimators and expanding the optical system vertically or horizontally, embodiments of the present invention increase the allowable number of multi-channel optical signals being switched by reconfiguring each collimator to receive and transmit more than one multi-channel optical signal at a time. In effect, each collimator can be configured to accommodate two or more different ports. This can be done using the same relay optics, wavelength separator, and focusing lens by applying the basic foundations of optical design discussed above (e.g., two optical signals entering the grating at the same point, but different angles).
[0024] FIGs. 3A-3B are schematic diagrams illustrating a wavelength switch system using angle multiplexing optics according to an embodiment of the present invention. FIG. 3A illustrates a top view of the WSS, while FIG. 3B provides a cross-sectional view of the same WSS. The WSS
300 comprises a collimator array
303, relay optics
305, a wavelength separator
307, focusing optics
309, and two deflector arrays
311, 312. The collimator array
303 may be made up of a plurality of collimator elements
304. Each collimator element
304 in the collimator array
303 may be configured to receive and transmit two or more multi-channel optical signals
301, 302 simultaneously over different optical paths corresponding to two or more different ports. The different optical paths may be implemented, e.g., using optical fibers or optical waveguides. For purposes of illustration, only two total multi-channel optical signals
301, 302 are being switched by the WSS
300 in our example. It is important to note that each input/output collimator may be configured to receive and transmit more than two multi-channel optical signals simultaneously.
[0025] By way of example, and not by way of limitation, each collimator element
304 may include a lens. Inbound multi-channel optical signals can be guided to the lens by different optical paths configured such that the lens deflects the optical signals at different angles. If the optical behavior of the lens is reversible, the collimator element
304 can likewise couple outbound optical signals incident on the lens at different angles to different optical paths.
[0026] Referring to FIG. 3B, a collimator
304 may receive two inbound multi-channel optical signals
301, 302. The collimator
304 is configured to direct these two multi-channel optical signals
301, 302 towards the relay optics
305 at different angles. The angles at which these two multi-channel optical signals
301,
302 leave the input port
304 can depend on the overall objectives of the WSS
300 and may vary from one WSS to another. The relay optics
305 then take each multi-channel optical signal
301, 302 and converts them into a corresponding spectral beam while simultaneously transforming different angles at which each signal exits the collimator
304 into different angles at which each beam is incident on the wavelength separator
307. Each spectral beam, which corresponds to a multi-channel optical signal, will meet the wavelength separator
307 at the same point
P, albeit at different angles. If the wavelength separator
307 is positioned at the focal plane of the focusing optics
309, the two spectral beams will behave in accordance with the basic foundations of optical design discussed above (i.e., they will exit the focusing optics in parallel).
[0027] The first multi-channel optical signal
301, represented by a solid line, is directed by the focusing optics
309 towards an array of channel deflective elements
312, which will hereinafter be referred to as deflector array B. The focusing optics
309 direct the second multi-channel optical signal
302, represented by the dotted line, towards a second array of channel deflective elements
312, which will hereinafter be referred to as deflector array A. The deflector arrays
311, 312 can then redirect the constituent channels towards an output port in a different collimator element
306 depending on the requirements of the WSS
300. By way of example, and not by way of limitation, the deflector elements in the deflector arrays may be microelectromechanical systems (MEMS) mirrors. However, embodiments of the present invention are not limited to implementations that utilize MEMS mirrors, alternatively, other types of deflector elements such as liquid crystal on silicon (LCOS) devices may be used. The deflector arrays
311,
312 can be oriented at an angle with respect to each other to accommodate different incident angles of the first and second optical signals
301,
302 on the arrays due to the different incident angles of the first and second optical signals
301, 302 on the wavelength separator
307.
[0028] It should be clear that each deflector array
311, 312 can function independently without affecting the other, because of their vertical arrangement within the WSS
300. Therefore, several optical signals (and thus several optical switching systems) may occupy the same physical space without interfering with each other. Specifically, by way of example, and not by way of limitation, embodiments of the present invention include implementations that allow two or more independent 1XN wavelength selective switches to be made in the same form factor as one 1XN wavelength selective switch. Whereas prior art required an increase in the number of collimators, and therefore an increase in the size of the optical components, embodiments of the present invention can take advantage of existing optical switch configurations. Embodiments of the present invention makes more economical use of each collimator, by allowing each collimator to receive and transmit more than one multi-channel optical signal. In other words, each collimator can accommodate more than one port. This in turn allows most of the optical components (i.e., relay optics, wavelength separator, and focusing optics) in the optical system to remain unaltered, minimizing the costs associated with switching a greater number of signals. While embodiments of the present invention might require an additional deflector array for each additional multi-channel optical signal being transmitted by a single collimator element, the overall cost of switching additional multi-channel optical signals can be reduced because most of the optical components used for the switching process, e.g., the relay optics, wavelength separator, and focusing optics, can be the same as in a conventional switch.
[0029] A concern associated with this type of angle-multiplexed WSS is that cross talk (or isolation) may occur between the two or more multi-channel optical signals. However, by controlling the angular separation between the multi-channel optical signals when they come in contact with the wavelength separator, cross talk may be easily kept below 40 dB.
[0030] FIGs. 4A-4B illustrate an example of how a single input collimator may be configured to receive and transmit two or more multi-channel optical signals via different optical paths. FIG. 4A illustrates a cross-sectional view of a multi-port collimator
400, while FIG. 4B illustrates an axial view of the collimator
400. By way of example, and not by way of limitation, a single collimator element may be configured to receive and transmit two multi-channel optical signals
401, 402 by positioning two separate waveguides
403A,
403B in front of a single lens
405. In this example, the waveguide paths
403A,
403B may be parallel to each other and parallel to an optical axis of the lens
405. In this example, the two waveguide paths
403A,
403B are offset with respect to each other. Each of the waveguide paths
403A,
403B directs its corresponding input multi-channel optical signal
401, 402 in parallel directions but towards different points on the lens
405. If the offset distance between the two waveguide paths is sufficiently large, the cross-talk between the two signals
401,
403 may be kept below about 40 dB. By way of example, and not by way of limitation, two waveguides that share the same lens can be offset by a separation distance that is about 2 times the width of the waveguide paths. For example, a typical waveguide width is on the order of 8 µm. In this case, the center-to-center distance between the two waveguides should be 16 µm or greater. It is important to note that an output port may also be configured to receive and transmit more than one multi-channel optical signal in a similar manner. It is noted that embodiments of the present invention include implementations in which a single collimator element can accommodate three or more ports for optical signals. As such, collimator elements in embodiments of the present invention are not limited to the configurations shown in FIGs. 4A-4D.
[0031] In alternative embodiments, each of the waveguide paths
403A, 403B could direct its corresponding input multi-channel optical signal towards the same point of the lens
405, but at different angles. In other alternative embodiments, the waveguide paths
403A,
403B could direct the optical signals
401,
402 toward different points on the lens
405 and at different angles.
[0032] While FIG. 4A-4B illustrate the configuration of a single input port, multiple input ports and output ports could be constructed using a similar setup as illustrated in FIG. 4C-4D. FIG. 4C provides a cross-sectional view of an array of input ports and output ports, wherein each port is configured to transmit and receive two multi-channel optical signals. FIG. 4D provides an axial view of that same array. A waveguide array
407 could be positioned in front of a lens array
409, such that two or more waveguides
403 are configured to direct their multi-channel optical signals toward the same lens
405. In the embodiment illustrated in FIGs. 4A-4B, each pair of waveguides
403 can share a single lens
405. The waveguide array (WGA)
407 could be implemented using planar lightwave circuit (PLC) technology which utilizes wafer processing techniques to form regular and repeatable patterns defined by photolithography. Using lithography, the spacing between the waveguide pairs can be matched precisely with the spacing of the lens array
409. Since the focal length of the lens array
409 can be made with extreme precision, the angular difference between the two or more groups of light exiting the collimator may also be very precisely controlled.
[0033] FIG. 3B illustrated an example of switching two multi-channel optical signals to different output ports. However, there may be times when it is necessary to couple the two different multi-channel optical signals into the same output port (i.e., cross-coupling). Using only the two deflector arrays
311,
312 provided in FIG. 3B to cross-couple two multi-channel optical signals might not be very straightforward, and thus additional optical components may need to be introduced to facilitate this process.
[0034] It is noted that the different waveguide paths for each collimator in the array
303 can be thought of as belonging to two different groups of optical ports. For example, the upper port in each collimator element may be thought of as belonging to one port group and the lower port in each collimator element may be thought of as belonging to a different port group. In the switch configuration shown in FIGs. 3A-3B, signals from a port in one port group can be coupled via a corresponding deflector array to any other port in the same port group. The switch of FIGs. 3A-3B may be modified to accommodate cross-coupling of optical signals between the different port groups.
[0035] FIG. 5A and 5B are schematic diagrams illustrating a WSS that employs angled-multiplexing and cross-coupling according to an embodiment of the present invention. As used herein, the term cross-coupling refers to coupling of signals from two different input ports to the same output port. FIG. 5A illustrates a top-view of a WSS
500 according to an alternative embodiment of the invention, while FIG. 5B presents a cross-sectional view of the same WSS. Rather than directing each multi-channel optical signal to a different set of output ports, this embodiment is set up such that multi-channel optical signals may be cross-coupled using angular exchange. For purposes of our example, we will illustrate how a single multi-channel optical signal
501 can be redirected from deflector array B
512 to deflector array A
511. Once the multi-channel optical signal
501 is redirected to deflector array A
511, it may then become coupled with a multi-channel optical signal that was initially directed towards deflector array A (not shown for purposes of illustration).
[0036] The WSS
500 comprises an array
503 of collimator elements
504, a set of relay optics
505, a wavelength separator
507, focusing optics
509, and two arrays of channel deflective elements
511,
512. These optical components are configured to switch one or more multi-channel optical signals to their respective output ports in a manner similar to that described above with respect to FIGs. 3A-3B. In addition to the optical components just described, the WSS
500 also includes an additional one-dimensional (1-D) reflector
515 to facilitate cross-coupling. The 1-D reflector
515 is inserted along an optical path between the wavelength separator
507 and the focusing optics
515. The 1-D reflector
515 includes one mirror
519 and two cylinder lenses
521, 523. The two cylinder lenses
521, 523 are configured to focus in a direction perpendicular to the plane of the drawing in FIG. 5B and do not focus in the vertical direction in FIG. 5B. For convenience, the cylinder lens closest to the focusing optics will be referred to herein as the 1
st cylinder lens
523. The cylinder lens situated between the mirror
519 and the 1
st cylinder lens
523 will be referred to herein as the 2
nd cylinder lens
521.
[0037] The 1
st cylinder lens
523 combines with the focusing optics
509 to form one effective lens. This effective lens and the 2
nd cylinder lens
521 are optically coupled to form a 4f optical system. As is well known, in a typical 4f optical system, two lenses of equal focal length f are separated from each other by a distance 2f. An input plane is located a distance f from one of the lenses and an output plane is located a distance f from the other lens on the opposite side. In FIG. 5B, the input plane could be located at deflector array A
511 or deflector array B
512 and the output plane could be located at the mirror
519 in the 1-D reflector. It is noted that the input and output planes could be reversed due to the reversible nature of optical signals. In this example, the 1
st cylinder lens
523 and the focusing optics have an effective focal length f and the second cylinder lens
521 has a focal length of f. Strictly speaking, a 4f system does not require that the focal lengths of the two lenses to be equal. If the two lenses
521, 523 have different focal lengths f1 and f2, a 4f optical system may be implemented if the lenses are configured such that the distance between the lenses is f1+f2 and the input/output planes are located at f1 and f2 respectively.
[0038] From the top view, if deflector array B
512 reflects light back along the optical axis, the 4f system will return the light back to the same position. However, from the side view of FIG. 5B, it can be seen that deflector array B
512 is actually oriented downwards. In the vertical direction of the drawing in FIG. 5B there are no optical focusing effects on light that passes through the cylinder lenses
521, 523, and so when light is reflected by deflector array B
512, the angle is changed. Because of the angle-position transform produced by the focusing optics
509, the change in angle will cause the light to be directed towards the 1-D reflector mirror
519, which will then focus the light at deflector array A
511. All light reflected by deflector array B
512 will be coupled with any groups of light initially directed at deflector array A
511. Thus, the 1-D retro reflector
515 provides a mechanism for angle exchange (AE).
[0039] This angle exchange concept can be extended for systems configured to receive/transmit more than two multi-channel optical signals per collimator element
504. This is illustrated in FIG. 5C, where the WSS
500' is configured to switch three multi-channel optical signals per input collimator element
504 using three arrays of deflective elements
511, 512, 517. A third deflector array
517, herein referred to as deflector array C
517 is introduced to facilitate switching of the third multi-channel optical signal associated with the input port. For purposes of illustration, only one multi-channel optical signal
501 is shown to describe the angular exchange between three deflector arrays
511, 512, 517. An additional mirror
520 is placed in the 1-D retro reflector
515' to facilitate angle exchange of light between deflector array B
512 and deflector array C
517. The 1-D retro reflector
515' behaves in the same manner as described above with respect to cross-coupling light deflected by deflector array A
511 and deflector array B
512. The additional mirror
520 is angled with respect to mirror
519 to facilitate cross-coupling of light reflected from deflector array B
512 with any groups of light initially directed at deflector array C
517.
[0040] In some embodiments of the invention, the WSS
500 may be configured to allow for cross-coupling between deflector array A
511 and deflector array C
517. The choice of whether the optical signal
501 hits mirror
519 or additional mirror
520 depends on the angle of deflector array B
512. If the angle of deflector array B
512 is adjusted slightly, the light can hit mirror
519 so that the angle of return light is altered so that by design the optical signal could return to deflector array A
511.
[0041] It is important to note that this concept of angle exchange illustrated in FIGs. 5A-5C may be adapted for any number of multi-channel optical signals and any number of arrays of channel deflective elements.
[0042] It is also noted that the WSS
500 can be configured to avoid cross-coupling between deflector arrays when this is not desired. For example, undesired cross-coupling may be avoided if the ID reflectors
519, 520 occupy a space that does not change the traditional 1xN WSS function. The ID reflectors
519, 520 could be located one channel space between the original optical path or the number of ports may be reduced by one compared to the original WSS design. Thus, the optical signal
501 could be made to stay in its own deflector array or the return beam could be moved to a ID reflector to cause the channel to change to a different deflector array. Each mirror
519,
520 can be configured to cause one kind of exchange of the signal from deflector array B
512 to deflector array C
517. Additional space allows for another mirror (tilted at different angle) to provide for exchange between deflector array B
512 and deflector array A
511.
[0043] Angle multiplexing and angle exchange provide WSS with significant advantages over the prior art in the areas of optical switching capacity and cross-coupling. They allow several multi-channel optical signals to share optical components, which reduce the costs associated with making additional optical components. They also allow several multi-channel optical signals to share the same physical space, thus reducing the overall size of the WSS as well as costs associated with expansion. Additionally, the ability to reduce the component count of a WSS leads to higher overall reliability.
[0044] While the primary application of angle-multiplexing optics and angular exchange involves wavelength switch systems, these concepts may also be applied to fiber switches as illustrated in FIG. 6A-B. FIG. 6A illustrates a top view of a fiber switch employing angle-multiplexing and angular exchange. FIG. 6B illustrates the cross-sectional view of the same optical switch. The switch
600 includes of a collimator array
603, a 1-D retro reflector
615, focusing optics
609 and three deflectors
611, 612, 617. These three deflector will be referred to herein as deflector A
611, deflector B
612, and deflector C
617. By way of example, and not by way of limitation, the deflectors
611, 612, 617 may include moveable mirrors, e.g., MEMS mirrors that can pivot about one or more axes to provide a desired optical coupling between different ports within a given port group in the collimator array
603.
[0045] The collimator array
603 is comprised of multiple collimator elements
604, 606 that are configured to receive and transmit optical signals. Each collimator element
604, 606 may be configured to receive two or more optical signals via different ports as described above. In the example shown in FIG. 6, each collimator element
604, 606 is configured to receive and transmit three optical signals at a given time. However, for purposes of illustration, only a single optical signal
601 will be shown to pass through the fiber switch
600. Once an input port in a first collimator element
604 has received the optical signal
601, it will direct that optical signal
601 towards a set of focusing optics
609.
[0046] The focusing optics
609 then direct the optical signal
601 towards a deflector, dependent on the configuration of the switch
600. As shown in the example illustrated, in FIG. 6B, the focusing optics
609 can be configured to direct the optical signal
601 towards deflector B
612. While WSS employ deflector arrays to redirect individual channels (i.e., wavelengths) of each multi-channel optical signal, the fiber switch
600 can be implemented with individual deflector elements to redirect an entire multi-channel optical signal without first separating the optical signal into its constituent channels. Deflector B
612 can be oriented to direct the optical signal
601 towards the 1-D retro reflector
615. The 1-D retro reflector
615 comprises two cylinder lenses and a mirror, and behaves as described above (i.e., it redirects light incident on it towards another mirror for cross-coupling). The two cylinder lenses and the focusing optics
609 can be configured to form a 4f optical system, e.g., as described above. In our example, the fiber switch
600 is arranged such that the 1-D retro reflector
615 redirects the optical signal from deflector B
612 to deflector C
617. The effect of this angular exchange is to cross couple the optical signal reflected by mirror B
612 with any optical signals initially incident on deflector C
617. It is important to note that angular exchange could be implemented between any number of combinations of deflector arrays.
[0047] While the above is a complete description of the preferred embodiment of the present invention, it is possible to use various alternatives, modifications, and equivalents. Therefore, the scope of the present invention should be determined not with reference to the above description, but should, instead, be determined with reference to the appended claims, along with their full scope of equivalents. Any feature described herein, whether preferred or not, may be combined with any other feature described herein, whether preferred or not. In the claims that follow,
the indefinite article "A" or "An" refers to a quantity of one or more of the item following the article, except where expressly stated otherwise. The appended claims are not to be interpreted as including means-plus-function limitations, unless such a limitation is explicitly received in a given claim using the phrase "means for".
1. A wavelength switch system (300, 500) for dynamic switching of multi-channel optical signals having spectral channels of different wavelengths, comprising:
a) a plurality of fiber collimator elements (304, 504) for optical signals having spectral channels, each fiber collimator element (304, 504) comprising two or more fiber collimator ports and two or more separate optical paths whereby the fiber collimator ports are configured to receive and transmit two or more corresponding independent optical signals at a time;
b) a wavelength separator (307, 507) configured to separate an optical signal into spectral channels;
c) relay optics (305, 405) optically coupled between the plurality of fiber collimator elements (304, 504) and the wavelength separator (307, 507), wherein the relay optics (305, 405) are configured to direct optical signals originating from a first fiber collimator port towards a common point on a wavelength separator (307, 507) but at different angles; and
d) two or more independent arrays of channel deflection elements (311, 312, 511, 512) optically coupled to the wavelength separator (307, 507), wherein each array of channel deflection elements (311, 312, 511, 512) is configured to selectively direct a group of spectral channels corresponding to one of the optical signals originating from the first collimator port toward a second fiber collimator port;
e) focusing optics optically coupled between the wavelength separator (307, 507) and the arrays of channel deflection elements (311, 312, 511, 512).
2. The system (300, 500) of claim 1 wherein two or more of the arrays of channel deflection elements (311, 312, 511, 512) are oriented at an angle with respect to each other to accommodate coupling of optical signals incident on the wavelength separator (307, 507) at different angles to respectively different arrays of channel deflection elements (311, 312, 511, 512).
3. The system (300, 500) of claim 1, wherein each fiber collimator element (304, 504) in the plurality of fiber collimator elements (304, 504) includes two or more waveguides and a single lens optically coupled to the two or more waveguides, wherein the two or more waveguides are separated by a fixed offset.
4. The system (300, 500) of claim 3 wherein the two or more waveguides are substantially parallel to each other.
5. The system (300, 500) of claim 4 wherein the fixed offset is about 2 times a width of the waveguides.
6. The system (300, 500) of claim 1, wherein the wavelength separator (307, 507) includes an interference filter, a polarizing filter, an arrayed waveguide grating, a prism, or a diffraction grating.
7. The system (300, 500) of claim 1, wherein the channel deflection elements (311, 312, 511, 512) of the two or more arrays include microelectromechanical system (MEMS) mirrors, liquid crystal on silicon (LCOS) devices, bi-stable liquid crystals, UV curable optical mediums, or photorefractive holographic gratings.
8. The system (300, 500) of claim 1, further comprising redirection optics configured to receive the group of spectral channels emanating from one of the two or more arrays of channel deflection elements (311, 312, 511, 512) and redirect said group of spectral channels towards another one of the two or more arrays of channel deflection elements (311, 312, 511, 512).
9. The system (300, 500) of claim 8, wherein the redirection optics (515) include two cylindrical lenses (521, 523) coupled to one or more redirection mirrors (516).
10. The system (300, 500) of claim 9, further comprising the focusing optics optically coupled between the arrays of channel deflection elements (311, 312, 511, 512) and the redirection optics (515), wherein the two cylindrical lenses (521, 523) and the focusing optics are configured to form a 4f optical system.
1. Wellenlängenschaltersystem (300, 500) zum dynamischen Schalten von optischen Mehrkanalsignalen, die Spektralkanäle für verschiedene Wellenlängen aufweisen, wobei das System Folgendes umfasst:
a) eine Vielzahl von Faserkollimatorelementen (304, 504) für optische Signale, die Spektralkanäle aufweisen, wobei jedes Faserkollimatorelement (304, 504) zwei oder mehr Faserkollimatoranschlüsse und zwei oder mehr separate optische Wege umfasst, wodurch die Faserkollimatoranschlüsse dazu konfiguriert sind, zwei oder mehr entsprechende unabhängige optische Signale gleichzeitig zu empfangen und zu übertragen;
b) einen Wellenlängentrenner (307, 507), der dazu konfiguriert ist, ein optisches Signal in Spektralkanäle zu trennen;
c) eine Relaisoptik (305, 405), die zwischen der Vielzahl von Faserkollimatorelementen (304, 504) und dem Wellenlängentrenner (307, 507) optisch gekoppelt ist, wobei die Relaisoptik (305, 405) dazu konfiguriert ist, optische Signale, die von einem ersten Faserkollimatoranschluss stammen, in Richtung eines gemeinsamen Punkts auf einem Wellenlängentrenner (307, 507), jedoch in unterschiedlichen Winkeln zu leiten; und
d) zwei oder mehr unabhängige Anordnungen von Kanalumlenkelementen (311, 312, 511, 512), die optisch an den Wellenlängentrenner (307, 507) gekoppelt sind, wobei jede Anordnung von Kanalumlenkelementen (311, 312, 511, 512) dazu konfiguriert ist, eine Gruppe von Spektralkanälen, die einem der optischen Signale, die von dem ersten Kollimatoranschluss stammen, entspricht, selektiv in Richtung eines zweiten Faserkollimatoranschlusses zu leiten;
e) eine Fokussierungsoptik, die zwischen dem Wellenlängentrenner (307, 507) und den Anordnungen von Kanalumlenkelementen (311, 312, 511, 512) optisch gekoppelt ist.
2. System (300, 500) nach Anspruch 1, wobei zwei oder mehr der Anordnungen von Kanalumlenkelementen (311, 312, 511, 512) in einem Winkel in Bezug aufeinander ausgerichtet sind, um das Koppeln von optischen Signalen, die auf den Wellenlängentrenner (307, 507) in verschiedenen Winkeln einfallen, an jeweilige verschiedene Anordnungen von Kanalumlenkelementen (311, 312, 511, 512) auszugleichen.
3. System (300, 500) nach Anspruch 1, wobei jedes Faserkollimatorelement (304, 504) in der Vielzahl von Faserkollimatorelementen (304, 504) zwei oder mehr Wellenleiter und eine einzelne Linse, die optisch an die zwei oder mehr Wellenleiter gekoppelt ist, beinhaltet, wobei die zwei oder mehr Wellenleiter durch einen festen Versatz voneinander getrennt sind.
4. System (300, 500) nach Anspruch 3, wobei die zwei oder mehr Wellenleiter im Wesentlichen parallel zueinander sind.
5. System (300, 500) nach Anspruch 4, wobei der feste Versatz etwa zweimal einer Breite der Wellenleiter entspricht.
6. System (300, 500) nach Anspruch 1, wobei der Wellenlängentrenner (307, 507) einen Interferenzfilter, einen Polarisierungsfilter, ein angeordnetes Wellenleitergitter, ein Prisma oder ein Diffraktionsgitter beinhaltet.
7. System (300, 500) nach Anspruch 1, wobei die Kanalumlenkelemente (311, 312, 511, 512) der zwei oder mehr Anordnungen Spiegel eines mikroelektromechanischen Systems (MEMS), Flüssigkristalleinrichtungen auf Siliziumbasis (LCOS-Einrichtungen), bistabile Flüssigkristalle, UV-härtbare optische Medien oder photorefraktive, holografische Gitter beinhalten.
8. System (300, 500) nach Anspruch 1, ferner umfassend eine Umleitungsoptik, die dazu konfiguriert ist, die Gruppe von Spektralkanälen zu empfangen, die von einer der zwei oder mehr Anordnungen von Kanalumlenkelementen (311, 312, 511, 512) ausgeht, und diese Gruppe von Spektralkanälen in Richtung einer anderen der zwei oder mehr Anordnungen von Kanalumlenkelementen (311, 312, 511, 512) umzuleiten.
9. System (300, 500) nach Anspruch 8, wobei die Umleitungsoptik (515) zwei zylindrische Linsen (521, 523) beinhaltet, die an einen oder mehrere Umleitungsspiegel (516) gekoppelt sind.
10. System (300, 500) nach Anspruch 9, ferner umfassend die Fokussierungsoptik, die zwischen den Anordnungen von Kanalumlenkelementen (311, 312, 511, 512) und der Umleitungsoptik (515) optisch gekoppelt ist, wobei die zwei zylindrischen Linsen (521, 523) und die Fokussierungsoptik dazu konfiguriert sind, ein optisches 4f-System zu bilden.
1. Système de commutation de longueur d'onde (300, 500) pour la commutation dynamique de signaux optiques multicanaux ayant des canaux spectraux de longueurs d'onde différentes, comprenant :
a) une pluralité d'éléments de collimateur de fibre (304, 504) pour des signaux optiques ayant des canaux spectraux, chaque élément de collimateur de fibre (304, 504) comprenant au moins deux ports de collimateur de fibre et au moins deux chemins optiques séparés, moyennant quoi les ports de collimateur de fibre sont configurés pour recevoir et transmettre au moins deux signaux optiques indépendants correspondants à la fois ;
b) un séparateur de longueur d'onde (307, 507) configuré pour séparer un signal optique en canaux spectraux ;
c) des optiques de relais (305, 405) couplées optiquement entre la pluralité d'éléments de collimateur de fibre (304, 504) et le séparateur de longueur d'onde (307, 507), dans lequel les optiques de relais (305, 405) sont configurées pour diriger des signaux optiques provenant d'un premier port de collimateur de fibre vers un point commun sur un séparateur de longueur d'onde (307, 507) mais à des angles différents ; et
d) au moins deux réseaux indépendants d'éléments de déviation de canal (311, 312, 511, 512) couplés optiquement au séparateur de longueur d'onde (307, 507), dans lequel chaque réseau d'éléments de déviation de canal (311, 312, 511, 512) est configuré pour diriger sélectivement un groupe de canaux spectraux correspondant à un des signaux optiques provenant du premier port de collimateur vers un deuxième port de collimateur de fibre ;
e) des optiques de focalisation couplées optiquement entre le séparateur de longueur d'onde (307, 507) et les réseaux d'éléments de déviation de canal (311, 312, 511, 512).
2. Système (300, 500) selon la revendication 1, dans lequel au moins deux des réseaux d'éléments de déviation de canal (311, 312, 511, 512) sont orientés à un angle l'un par rapport à l'autre pour permettre un couplage de signaux optiques incidents sur le séparateur de longueur d'onde (307, 507) à des angles différents aux réseaux respectivement différents d'éléments de déviation de canal (311, 312, 511, 512).
3. Système (300, 500) selon la revendication 1, dans lequel chaque élément de collimateur de fibre (304, 504) dans la pluralité d'éléments de collimateur de fibre (304, 504) comprend au moins deux guides d'onde et une unique lentille couplée optiquement aux au moins deux guides d'onde, dans lequel les au moins deux guides d'onde sont séparés d'un décalage fixe.
4. Système (300, 500) selon la revendication 3, dans lequel les au moins deux guides d'onde sont sensiblement parallèles l'un à l'autre.
5. Système (300, 500) selon la revendication 4, dans lequel le décalage fixe est environ 2 fois une largeur des guides d'onde.
6. Système (300, 500) selon la revendication 1, dans lequel le séparateur de longueur d'onde (307, 507) comprend un filtre d'interférence, un filtre polarisant, une grille de guides d'onde en réseau, un prisme ou une grille de diffraction.
7. Système (300, 500) selon la revendication 1, dans lequel les éléments de déviation de canal (311, 312, 511, 512) des au moins deux des réseaux comprennent des miroirs de microsystème électromécanique (MEMS), des dispositifs à cristaux liquides sur silicium (LCOS), des cristaux liquides bistables, des milieux optiques durcissables aux UV ou des grilles holographiques photo-réfractives.
8. Système (300, 500) selon la revendication 1, comprenant en outre des optiques de redirection configurées pour recevoir le groupe de canaux spectraux émanant d'un des au moins deux des réseaux d'éléments de déviation de canal (311, 312, 511, 512) et rediriger ledit groupe de canaux spectraux vers un autre des au moins deux des réseaux d'éléments de déviation de canal (311, 312, 511, 512).
9. Système (300, 500) selon la revendication 8, dans lequel les optiques de redirection (515) comprennent deux lentilles cylindriques (521, 523) couplées à un ou plusieurs miroirs de redirection (516).
10. Système (300, 500) selon la revendication 9, comprenant en outre les optiques de focalisation couplées optiquement entre les réseaux d'éléments de déviation de canal (311, 312, 511, 512) et les optiques de redirection (515), dans lequel les deux lentilles cylindriques (521, 523) et les optiques de focalisation sont configurées pour former un système optique 4f.