The application relates to all optical networking (AON) generally and more particularly to add-drop multiplexing (ADM) nodes in AON applications.
In order to allow one or more optical channel wavelengths to be added to and/or dropped from an optical signal that is otherwise passing through an optical node within an all optical network, some form of optical add-drop multiplexing functionality may be implemented in such nodes.
An optical signal may pass through a number of optical nodes as it traverses an all optical network. From a link budgeting perspective, it is therefore generally advantageous to minimize optical losses that an optical signal may incur as it passes through an optical node, including losses that may be incurred through the add-drop multiplexing functionality.
An embodiment provides an apparatus for all optical networking (AON) that includes a tunable optical filter and a demultiplexer. The tunable optical filter has an incoming optical input port to receive an incoming optical signal, a drop optical output port and an outgoing optical output port. The tunable optical filter is controllable to drop a first portion of the incoming optical signal in a first wavelength band to the drop optical output port and pass a second portion of the incoming optical signal in a second wavelength band to the outgoing optical output port. The demultiplexer is optically connected to the drop optical output port of the tunable optical filter and is configured to distribute the dropped first portion of the incoming optical signal in the first wavelength band among local drop optical output ports.
The tunable optical filter may be configured to lower an optical loss between the incoming optical input port and the outgoing optical output port in the second wavelength band at the account of a corresponding increase of an optical loss between the incoming optical input port and the drop optical output port in the first wavelength band.
The tunable optical filter may be wavelength-tunable, bandwidth-tunable, or both. For example, the tunable optical filter may be wavelength-tunable to adjust a center wavelength of the first wavelength band and/or bandwidth-tunable to adjust bandwidth of the first wavelength band.
In some cases, the tunable optical filter may be implemented with a tunable Mach-Zehnder Interferometer and Resonator Ring (MZI/RR) hybrid optical filter.
In some such cases, the tunable MZI/RR hybrid optical filter may include a tunable RR filter that includes a resonator ring and a variable optical coupler. The variable optical coupler may be controllable to adjust the bandwidth of the tunable RR filter.
The tunable optical filter may also include an add optical input port. In which case, the tunable optical filter may be configured to add an add optical input signal in a third wavelength band from its add optical input port to its outgoing optical output port. The apparatus may further include a multiplexer configured to combine local add optical input signals in the third wavelength band from local add optical input ports into the add optical input signal.
In some implementations, the tunable optical filter may be implemented with two three-port tunable optical filters. A first to the two three-port tunable optical filter may be controllable to drop the first portion of the incoming optical signal in the first wavelength band to the drop optical output port and pass the second portion of the incoming optical signal in the second wavelength band to a pass optical output port. The second of the two three-port tunable optical filters may be controllable to add an add optical input signal in the third wavelength band from the add optical input port to the outgoing optical output port and pass the second portion of the incoming optical signal in the second wavelength band from the pass optical output port of the first three-port tunable optical filter to the outgoing optical output port.
In some such cases, the first three-port tunable optical filter is configured to lower an optical loss in the passed second portion of the incoming optical signal in the second wavelength band at the account of a corresponding increase of an optical loss in the dropped first portion of the incoming optical signal in the first wavelength band. Similarly, the second three-port tunable optical filter may be configured to lower an optical loss in the passed second portion of the incoming optical signal in the second wavelength band at the account of a corresponding increase of an optical loss in the add optical input signal in the third wavelength band.
The demultiplexer may include multiple 1×2 optical splitters arranged to distribute the dropped first portion of the incoming optical signal in the first wavelength band among the local drop optical output ports.
In other embodiments, the demultiplexer may include multiple 1×2 optical switches configured as variable splitters controllable to selectively distribute the dropped first portion of the incoming optical signal in the first wavelength band among the local drop optical output ports.
In some embodiments, the tunable optical filter is a main tunable optical filter, and the demultiplexer is implemented with multiple additional tunable optical filters arranged in a cascade, with a first tunable optical filter in the cascade optically connected to the drop optical output port of the main tunable optical filter to receive the dropped first portion of the incoming optical signal in the first wavelength band. In such implementations, each tunable optical filter in the cascade may be tunable to drop a respective portion of the dropped first portion of the incoming optical signal to a respective local drop optical output port of the local drop optical output ports. The tunable optical filters in the cascade may each be wavelength-tunable to drop a respective channel wavelength in the first wavelength band.
Similarly, the multiplexer may be implemented with multiple tunable optical filters arranged in a cascade, with a last tunable optical filter in the cascade optically connected to the add optical input port of the main tunable optical filter to transmit the add optical input signal in the third wavelength band. In such implementations, each tunable optical filter in the cascade may be tunable to add a respective local add optical input signal from a respective local add optical input port into the add optical input signal for the main tunable optical filter. The tunable optical filters in the cascade may each be wavelength-tunable to add a respective channel wavelength in the third wavelength band.
Another embodiment provides a method related to drop functionality for optical add-drop multiplexing in all optical networking. The method includes controlling a tunable optical filter to drop a first portion of an incoming optical signal in a first wavelength band and pass a second portion of the incoming optical signal in a second wavelength band. The method further includes distributing the dropped first portion of the incoming optical signal in the first wavelength band among local drop optical output ports.
In some embodiments, controlling the tunable optical filter involves configuring the tunable optical filter to lower an optical loss in the passed second portion of the incoming optical signal in the second wavelength band at the account of a corresponding increase of an optical loss in the dropped first portion of the incoming optical signal in the first wavelength band.
In some cases, controlling the tunable optical filter involves wavelength-tuning the tunable optical filter to adjust a center wavelength of the first wavelength band, bandwidth-tuning the tunable optical filter to adjust bandwidth of the first wavelength band, or both.
In order to provide add functionality, the method may further include combining local add optical input signals in a third wavelength band into an add optical input signal and controlling the tunable optical filter to add the add optical input signal to the passed second portion of the incoming optical signal in the second wavelength band.
In some implementations, the tunable optical filter may be implemented with two three-port tunable optical filters. In such implementations, the method may include controlling a first three-port tunable optical filter to drop the first portion of the incoming optical signal in the first wavelength band and pass the second portion of the incoming optical signal in the second wavelength band, and controlling a second three-port tunable optical filter to add the add optical input signal in the third wavelength band to the passed second portion of the incoming optical signal in the second wavelength band. In some such cases, controlling the first three-port tunable optical filter involves configuring the first three-port tunable optical filter to lower an optical loss in the passed second portion of the incoming optical signal in the second wavelength band at the account of a corresponding increase of an optical loss in the dropped first portion of the incoming optical signal in the first wavelength band. Similarly, controlling the second three-port tunable optical filter may involve configuring the second three-port tunable optical filter to lower an optical loss in the passed second portion of the incoming optical signal in the second wavelength band at the account of a corresponding increase of an optical loss in the add optical input signal in the third wavelength band.
In some implementations, distributing the dropped first portion of the incoming optical signal in the first wavelength band among local drop optical output ports involves controlling multiple tunable optical filters arranged in a cascade. For example, each tunable optical filter in the cascade may be operable to drop a respective portion of the dropped first portion of the incoming optical signal to a respective local drop optical output port. In some such embodiments, controlling the multiple tunable optical filters arranged in the cascade involves wavelength-tuning one or more of the tunable optical filters to each drop a respective channel wavelength in the first wavelength band.
Similarly, in those embodiments in which the method further includes combining local add optical input signals in the third wavelength band into the add optical input signal, such combining may involve controlling multiple tunable optical filters arranged in a cascade. For example, each tunable optical filter in the cascade may be tunable to add a respective local add optical input signal from a respective local add optical input port into the add optical input signal. In some such embodiments, controlling the multiple tunable optical filters arranged in the cascade involves wavelength-tuning one or more of the tunable optical filters to each add a respective channel wavelength in the third wavelength band.
Embodiments will now be described with reference to the attached drawings in which:
As noted above, optical add and/or drop multiplexing functionality may be included in an optical node of an all optical network in order to allow one or more optical channel wavelengths to be added to and/or dropped from an optical signal that is otherwise passing through the optical node.
One conventional way to implement optical add-drop multiplexing functionality utilizes a wavelength-selective switch structure that includes an optical switch fabric arranged between first and second arrayed waveguides (AWGs). The optical switch fabric allows optical channel wavelength components separated from an incoming optical signal by the first AWG to be either switched to local optical drop ports to be “dropped” from the incoming optical signal or switched to the second AWG to be recombined into an outgoing optical signal, which results in the optical channel wavelength components being “passed” from the incoming optical signal to the outgoing optical signal. The optical switch fabric may also allow optical channel wavelength components from local optical add ports to be switched to the second AWG to be combined in the outgoing optical signal, and thus, “added” to the outgoing optical signal.
However, such implementations have some potential drawbacks, including losses incurred through the AWGs and the optical switch fabric, which can be particularly problematic in implementations where an optical signal may traverse through several nodes on its way from its source to its destination. Such losses may be accounted for by launching the optical signal with a higher initial transmission power and/or utilizing optical repeaters with optical amplifiers at intermediate locations within an optical network in order to boost optical transmission power. However, the use of higher power optical transmitters and/or installing optical repeaters often comes at the expense of increased costs and equipment complexity.
In addition, the AWGs used in such structures often have fixed channel spacings that are designed to be aligned with the channel spacings of a telecommunications standard, such as the International Telecommunications Union (ITU) grid channel spacings for Dense Wavelength Division Multiplexing (DWDM) in the C-Band with 50, 100 or 200 GHz channel spacings. However, should the channel spacings in a given standard be changed and/or should different channel spacings otherwise be wished to be used, then AWGs with fixed channel spacings aligned with the previously used channel spacings may not be usable with new/altered channel spacings.
In many applications, the number of degrees or directions that an optical node transmits and receives optical signals is limited to two and only a very small percentage of channel wavelengths are added/dropped at any given node.
In one aspect of the present invention, optical add-drop multiplexing functionality is implemented for all optical networking using tunable optical filters to add and/or drop channel wavelengths/bands. In particular, embodiments of the present invention provide an apparatus for all optical networking in which tunable optical filters are used to drop and/or add channel wavelengths/bands in drop and/or add bands, and to pass channel wavelengths/bands in a pass band. For the dropped and/or added channel wavelengths/bands in the drop and/or add bands, a multiplexer may be used to combine local add channel wavelengths/bands from local add ports, and a demultiplexer may be used to distribute local drop channel wavelengths/bands among local drop ports. According to such embodiments, the center wavelength and/or the bandwidth of the pass, add and/or drop bands may be tunable/controllable. As discussed in further detail below, such structures can potentially provide cost effective and customizable apparatuses for Add-Drop Multiplexing, particularly for Metro applications.
A brief description of a few example optical filter structures will now be provided with reference to
In operation, the optical coupler 16 couples a portion of an optical input signal received at In into the optical resonator ring 12. When optical waves in the optical resonator ring 12 build up a round trip phase shift that equals an integer multiple of 2π, the waves interfere constructively and the ring is in resonance.
Filtering properties of the optical resonator ring structure 10 are mainly determined by ring properties such as length, loss, and coupling efficiencies in the optical coupler 16.
For illustrative purposes, if continuous wave operation is assumed, and also assuming that reflections back into the waveguide 14 are negligible, which may not be practical in many implementations, it can be shown that the transfer function, Tn, expressed in terms of intensity transmission is equal to:
where a is the round trip loss coefficient, including both propagation loss in the ring 12 and loss in the coupler 16, r is a self-coupling coefficient of the coupler 16, φ is the single-pass round trip phase shift of the ring 12 and is equal to φ=βL, where L is the round trip length of the ring 12 and β is the propagation constant of the circulating mode.
As noted above, r is the self-coupling coefficient of the coupler 16. As shown in
The ring 12 is resonant when the phase φ is a multiple of 2π, or when the wavelength of the light fits an integer number of times inside the optical length of the ring 12.
For an ideal ring with zero or near-zero attenuation, i.e., a≈1, the transmission is unity for all values of detuning φ. Under critical coupling, when the coupled power is equal to the power loss in the ring, 1−a2=k2 or r=a, the transmission at resonance drops to zero. The phase argument of the field transmission varies periodically with frequency. The all-pass resonator based filter structure 10 delays an incoming optical signal via the temporary storage of optical energy within the resonator ring 12.
While the optical coupler 16 is shown as a discrete element in
The optical resonator ring structure 10 shown in
The optical resonator ring structure 20 includes a first optical waveguide 24 optically coupled to an optical resonator ring 22 through a first optical coupler 26, and a second optical waveguide 28 optically coupled to the optical resonator ring 22 through a second optical coupler 30. The first optical waveguide 24 has an optical input “In” and an optical output “Pass”. The second optical waveguide 28 has an optical input “Add” and an optical output “Drop”.
In operation, the first optical coupler 26 couples a portion of an optical input signal received at In into the optical resonator ring 22. The second optical coupler 30 couples a portion of the optical input signal circulating in the optical resonator ring 22 from the ring to the second optical waveguide 28 where it propagates to the optical Drop output. Similarly, the second optical coupler 30 couples a portion of an optical add signal received at Add into the optical resonator ring 22, and the first optical coupler 26 couples a portion of the optical add signal circulating in the optical resonator ring 22 from the ring to the first optical waveguide 24 where it propagates to the optical Pass output. Effectively, the optical coupler 30 plays the role of a filter, allowing a portion of the light received from Add to be forwarded to the Pass port. Similarly, the optical coupler 26 has mainly functions as a filter, allowing portions of the light received from the In port to be forwarded to the Drop and Pass ports. In practice, it may be desirable to not have a substantial amount of light going from Add to Drop, which means that there can be some design considerations and trade-offs when designing the coupling coefficients of the optical couplers 26 and 30, for example.
As with the optical resonator ring structure 10 shown in
For illustrative purposes, if continuous wave operation is again assumed, and also assuming that reflections back into the waveguide 24 are negligible, which may not be practical in many implementations, it can be shown that the transfer function, Tp, from the optical input In to the optical output Pass, and the transfer function, Td, from the optical input In to the optical output Drop, expressed in terms of intensity transmission are equal to:
where a is the round trip loss coefficient, including both propagation loss in the ring 22 and losses in the couplers 26 and 30, r1 is a self-coupling coefficient of the first coupler 26, r2 is a self-coupling coefficient of the second coupler 30, φ is the single-pass round trip phase shift of the ring 22 and is equal to φ=βL, where L is the round trip length of the ring 22 and β is the propagation constant of the circulating mode.
The first and second optical couplers 26 and 30 also each have a cross-coupling coefficient, k1 and k2, respectively. The power spitting ratios for the first coupler 26 are r12 and k12. If there are no losses in the first coupler 26, then the power splitting ratios of the first coupler can be assumed to satisfy the relationship r12+k12=1. Similarly, The power spitting ratios for the second coupler 30 are r22 and k22. If there are no losses in the second coupler 30, then the power splitting ratios of the second coupler can be assumed to satisfy the relationship r22+k22=1.
The ring 22 is resonant when the phase φ is a multiple of 2π, or when the wavelength of the light fits an integer number of times inside the optical length of the ring 22.
If the attenuation is negligible, i.e., a≈1, critical coupling occurs when the cross-coupling coefficients of the first and second optical couplers are symmetric, i.e., k1=k2. For a lossy resonator ring structure, it can be shown that critical coupling occurs when the losses match the coupling according to r2a=r1.
While the foregoing has discussed the transfer functions between the optical input In and the optical outputs Pass and Drop of the optical ring resonator structure 20, a similar discussion of the transfer functions between the optical input Add and the optical outputs Pass and Drop is omitted for the sake of conciseness.
For illustrative purposes, the roundtrip loss coefficient, a, and the self-coupling coefficients, r, r1, and r2, have been assumed to be as follows: a=0.85, r=r1=r2=0.9. However, it is to be appreciated that these values were chosen for illustrative purposes only and other values may be used. It is noted that because of the additional losses introduced by the second coupler 30, the transmission spectrum, Tp, for the Pass output of the add-drop optical resonator ring structure 20 has a broader notch than that of the transmission spectrum, Tn, of the all-pass or notch filter optical resonator ring structure 10. Also, the coupling for the add-drop optical resonator ring structure 20 is further from critical coupling, resulting in a smaller extinction ratio, i.e., ERp<ERn. It is also noted that the peaks for the transmission spectrum of the Drop output, Td, of the add-drop optical resonator ring structure 20 at 0 and 2π of detuning are less than the transmission peaks for the transmission spectrum of the Pass output, Tp, indicating that drop channels experience greater attenuation than pass or transit channels.
Some additional spectral features that are not explicitly indicated in
The FSR for an optical resonator ring structure can be calculated by the length of the ring (including all coupler(s), ring(s), etc.). Equation 4 shows the dependency of the FSR to the physical parameter of the ring
where c is the speed of light in vacuum, ng is the effective refractive index of the optical waveguide material used to implement the ring structure, and L is the total length of the ring. Note that for a circular ring with radius of R, we have L=2πR. In accordance with Equation 4, it can be shown that an FSR of greater than 1 THz can potentially be realized for a ring length of 50 micrometers and a refractive index ng of 4.2, which is the refractive index of silicon in one particular example of silicon on insulator (SOI) technology.
A finesse factor for a resonator may be defined as the ratio of FSR and the FWHM resonance width as follows:
where λres is the center wavelength of resonance of the resonator ring structure.
Similarly, a quality factor, Q, for a resonator may be defined as a measure of the sharpness of resonance relative to its central frequency according to:
The physical meaning of the finesse and quality factors relates to the number of round-trips made by the energy in the resonator ring structure before being lost to internal loss and the optical waveguides.
The 3 dB bandwidth of an optical resonator ring structure can be expressed in terms of the FSR and quality factor Q as follows:
In equation 7, r represent the coupling efficiency of the resonator ring structure. When the resonator ring structure also imposes some loss in the ring, that loss should be incorporated into r in equation 7.
While
In other approaches, other structures, such as a Mach-Zehnder Interferometer (MZI) structure, may be employed to potentially improve optical resonator ring based filters.
For example, utilizing an MZI structure in conjunction with a resonator ring structure similar to the all-pass resonator ring structure 10 shown in
Some general background on optical filtering has been provided above. Illustrative examples of how optical filtering, and particularly tunable optical filtering, may be leveraged to provide practical add and/or drop functionality for all optical networking in accordance with various embodiments of the present invention will now be discussed with reference to
In operation, the incoming optical input port 84 receives an incoming optical signal and the tunable optical filter 82 is controllable to drop a first portion of the incoming optical signal in a first wavelength band to the drop optical output port 86 and pass a second portion of the incoming optical signal in a second wavelength band to the outgoing optical output port 88. The drop demultiplexer 90 distributes the dropped first portion of the incoming optical signal in the first wavelength band among the local drop optical output ports 92.
Tunable optical filter 82 and drop demultiplexer 90 may be implemented in a silicon photonics fabrication technology in some embodiments.
A skilled person will understand that tunable optical filter 82 may have one or more control and/or monitoring inputs/outputs to allow for its control; however, such input(s)/output(s) are omitted in the drawing to avoid clutter. For the same reason, control and/or monitoring inputs/outputs have also been omitted in the other drawings.
In some embodiments, tunable optical filter 82 is wavelength-tunable, meaning that the center wavelength of the first wavelength band is adjustable. For example, in some embodiments tunable optical filter 82 may be wavelength-tunable such that the center wavelength of the first wavelength band is tunable across substantially the entire C band spectrum in the wavelength range 1530-1565 nm.
In some embodiments, the tunable optical filter 82 is bandwidth-tunable, meaning that the bandwidth of the first wavelength band is adjustable. For example, in some embodiments tunable optical filter 82 may be bandwidth-tunable such that the bandwidth of the first wavelength band is adjustable from 50 GHz to 500 GHz. With a 50 GHz spacing per channel, a 500 GHZ bandwidth for the first wavelength band could potentially allow up to 10 channels to be dropped. However, it is to be understood that this range is merely one very specific example; other embodiments may have different upper and lower bounds of bandwidth tunability.
There are many possibilities for how the drop demultiplexer 90 may be configured to distribute the dropped first portion of the incoming optical signal in the first wavelength band among the local drop optical output ports 92. For example, in some cases, drop demultiplexer 90 may be configured to split the dropped first portion of the incoming optical signal among each of the local drop optical output ports. In some cases this split may be substantially equal amongst the local drop optical output ports, while in other cases it may be unequal, with some local drop optical output ports outputting a greater portion of the power of the dropped first portion of the incoming optical signal in the first wavelength band. In other embodiments the distribution among the local drop optical output ports is wavelength-selective, such that specific channel wavelength(s) within the first wavelength band are distributed to specific local drop optical output port(s).
In some embodiments, the second portion of the incoming optical signal that is passed to the outgoing optical output port 88 includes multiple second wavelength bands. In some such cases, the second wavelength bands are non-contiguous, and the first wavelength band may be located intermediate two of the second wavelength bands.
It is noted that
While
An apparatus that implements both drop and add functionality to implement an optical ADM will now be described with reference to
In operation, the drop functionality of the apparatus 100 is similar to that of the apparatus 80 shown in
Tunable optical filter 102, drop demultiplexer 110 and add multiplexer 116 may be implemented in a silicon photonics fabrication technology in some embodiments.
In some embodiments, the tunable optical filter 102 is tunable in terms of bandwidth, center wavelength, or both.
In some embodiments, the tunable optical filter 102 is configured so that the third wavelength band and the first wavelength band are non-overlapping. In other embodiments, the tunable optical filter 102 is configured so that the third wavelength band and the first wavelength band at least partially overlap.
Various examples of structures that may be used to implement the tunable optical filter 102, the drop demultiplexer 110 and the add multiplexer 116 will now be discussed with reference to
In operation, an incoming optical input signal is received at the incoming optical input port 204. The incoming optical input signal may include one or more channel wavelengths in a first wavelength band and one or more channel wavelengths in a second wavelength band. The first 2×2 optical coupler 220 couples an incoming optical input signal from the incoming optical input port 204 onto the first optical path 224 and the second optical path 226. The first 2×2 optical coupler 220 also couples an add optical input signal from the add optical input port 214 onto the first optical path 224 and the second optical path 226. The second 2×2 optical coupler 222 couples an optical signal that has propagated over the first optical path to the outgoing optical output port 208 and to the drop optical output port 206. The second 2×2 optical coupler 222 also couples an optical signal that has propagated over the second optical path to the outgoing optical output port 208 and to the drop optical output port 206. The tunable optical filters 228 and 230 optically coupled to the first and second optical paths 224 and 226, respectively, are tunable to filter the optical signals propagating through the first and second optical paths 224 and 226 to cause a first portion of the incoming optical signal in a first wavelength band to be dropped to the drop optical output port 206, to cause a second portion of the incoming optical signal in a second wavelength band to be passed to the outgoing optical output port 208, and to cause a portion of an add optical input signal in a third wavelength band from the add optical input port 214 to be added to the outgoing optical output port 208.
It can be shown that the transfer function for the MZI based tunable filter structure 202 can be expressed as follows:
where EOutgoing, EDrop, EIncoming and EAdd are intensities of the outgoing optical signal at the outgoing optical output port 208, the drop optical output signal at the drop optical output port 206, the incoming optical input signal at the incoming optical input port 204 and the add optical input signal at the add optical input port 214, respectively, and T11, T12, T21 and T22 are the elements of a transfer matrix T.
The elements of the transfer matrix T can be expressed in terms of the transfer functions H1(s) and H2(s) of the first and second tunable optical filters 228 and 230, and the coupling efficiencies of the first and second 2×2 optical couplers 220 and 222. If both of the 2×2 optical couplers 220 and 222 have the same coupling efficiency, k, the elements T11, T12, T21 and T22 of the transfer matrix T can be formulated as follows:
T
11=(kH1+(1−k)H2)
T
12
=j√{square root over (k(1−k))}(H1+H2)
T
21
=j√{square root over (k(1−k))}(H1+H2)
T
22=−(1−k)H1+kH2
It is noted that the assumption that both of the 2×2 optical couplers 220 and 22 have the same coupling efficiency, k, has been made above in the interest of simplifying the expressions for the elements T11, T12, T21 and T22. However, more generally the two couplers can have different coupling efficiencies which leads to a more complicated expression for the transfer functions.
From equation 8, it can be seen that the intensity of the outgoing optical output signal at the outgoing optical output port 208 can be expressed as follows:
E
Outgoing
=T
12
E
Add
+T
11
E
Incoming (9)
By approximation and assuming that the filtering implemented by the MZI based tunable optical filter structure 202 acts transparently to transit channel wavelengths (channel wavelengths in the second wavelength band that are passed from the Incoming optical input port 204 to the Outgoing optical output port 208) and add channel wavelengths (channel wavelengths in the third wavelength band that are added from the Add optical input port 214 to the Outgoing optical output port 208), then it can be shown that the loss distribution follows T112+T122≈1, which means that there is a trade-off between the incoming transit channels and the added channels. For the purposes of link budget optimization it may be desirable to exploit this trade-off so that losses experienced by transit channels are reduced or minimized in trade for increased losses incurred by locally added/dropped channels.
In some embodiments, the first tunable optical filter 228 optically coupled to the first optical path 224 and/or the second tunable optical filter 230 optically coupled to the second optical path 226 may be implemented with a tunable resonator ring filter. Examples of tunable resonator ring filters are discussed later with reference to
In some embodiments, the first 2×2 optical coupler 220 and the second 2×2 optical coupler 222 may be implemented with variable directional couplers with a variable coupling efficiency, k, to provide power adjustment capability between the optical input ports of the first optical coupler 220 and the optical output ports of the second optical coupler 222.
In some embodiments, the tunable optical filters 228 and 230 are tunable in terms of bandwidth, center wavelength, or both.
When utilizing a tunable optical filter structure such as the one shown in
Tunable optical filters 228 and 230, optical paths 224 and 226 and 2×2 optical couplers 220 and 222 may be implemented in a silicon photonics fabrication technology in some embodiments.
While the tunable optical filter structure 202 utilizes two tunable optical filters 228 and 230 in a parallel arrangement in the parallel optical paths 224 and 226 of an MZI based optical filter structure to implement the add and drop functionalities of an ADM, in other embodiments a serial arrangement of two tunable optical filters may be utilized to implement add and drop functionalities. In such arrangements, the add and drop functionalities may be separated. For example, in a serial arrangement of tunable optical filters, the drop functionality may be implemented in a first tunable optical filter, with the add functionality implemented in a subsequent tunable optical filter, which means that add channels added via the add functionality of the subsequent tunable optical filter could potentially overlap, in terms of channel wavelength, with drop channels that were dropped via the drop functionality of the first tunable optical filter, without causing a collision problem.
An example of such a serial arrangement will now be discussed with reference to
In operation, for an incoming optical signal received at the incoming optical input port 304, the first three-port tunable optical filter 316 is controllable to drop a first portion of the incoming optical signal in the first wavelength band to the drop optical output port 306 and to pass a second portion of the incoming optical signal in a second wavelength band to the pass optical output port 320. Similarly, the second three-port tunable optical filter 318 is controllable to pass the second portion of the incoming optical signal in the second wavelength band from its pass optical input port 322 to the outgoing optical output port 308, and to also add an add optical input signal in a third wavelength band from the add optical input port 314 to the outgoing optical output port 308.
In some embodiments, the three-port tunable optical filters 316 and 318 are tunable in terms of bandwidth, center wavelength, or both.
The three-port tunable optical filters 316 and 318 may be implemented in a silicon photonics fabrication technology in some embodiments.
For illustrative purposes, example implementations of the first and second three-port tunable optical filters 316 and 318 will now be discussed with reference to
The tunable optical filter 316 shown in
In the illustrated example, the tunable RR filter 338 includes a resonator ring 342 and a variable optical coupler 340 optically coupling the resonator ring 342 to the first optical path 334. The resonator ring 342 includes a wavelength-tuning element 344. The variable optical coupler 340 of the tunable RR filter 338 is based on a MZI structure that includes a third optical coupler 346, a fourth optical coupler 348, a third optical path 350 and a fourth optical path 352. The third optical coupler 346 has a first optical input port optically connected to one end of an optical waveguide of the resonator ring 342, a second optical input port optically connected to the first optical output port of the first optical coupler 330, a first optical output port optically connected to the third optical path 350, and a second optical output port optically connected to the fourth optical path 352. The fourth optical coupler 348 has a first optical input port optically connected to the third optical path 350, a second optical input port optically connected to the fourth optical path 352, a first optical output port optically connected to an opposite end of the optical waveguide of the resonator ring 342, and a second optical output port optically connected to the first optical input port of the second optical coupler 332. The fourth optical path 352 includes a controllable optical phase shifter 354.
In operation, an incoming optical input signal is received at the incoming optical input port 304 and is coupled onto the first and second optical paths 334 and 336 by the first optical coupler 330. The tunable RR filter 338 is tunable to filter an optical signal propagating through the first optical path 334 to cause a first portion of an incoming optical signal in a first wavelength band to be dropped to the drop optical output port 306, and to cause a second portion of the incoming optical signal in a second wavelength band to be passed to the pass optical output port 320.
The controllable optical phase shifter 356 is controllable to adjust a relative optical phase shift between the first optical path 334 and the second optical path 336 in order to control the switching functionality of the MZI structure.
The controllable optical phase shifter 354 of the variable optical coupler 340 is controllable to adjust the optical coupling between the resonator ring 342 and the first optical path 334 by adjusting a relative optical phase shift between the third optical path 350 and the fourth optical path 352. With reference again to
While the MZI structure of the variable optical coupler 340 includes the controllable optical phase shifter 354 in the fourth optical path 352, in other embodiments the controllable optical phase shifter may be included in the third optical path 350 rather than in the fourth optical path 352. In still other embodiments, the third and fourth optical paths 350 and 352 may both include a controllable optical phase shifter.
In some embodiments, the controllable optical phase shifters 354 and 356 may be implemented with thermo-optical phase shifters or carrier injection optical phase shifters.
In some embodiments, the optical couplers 330, 332, 346 and 348 may be implemented with multimode interference (MMI) couplers or adiabatic couplers.
The total phase change experienced in a resonator ring can be expressed as follows:
φ=φ0+KL (10)
where φ is the total phase change experienced in the resonator ring, φ0 accounts for any undesired or unknown initial phase of the resonator ring, K is the propagation constant of the resonator ring and L is the length of the resonator ring. It is noted that the propagation constant K can be expressed in terms of wavelength, λ, or frequency, f, as follows:
where c is the speed of light in the waveguide of the ring. It is further noted that for a circular resonator ring with a radius R, the length of the ring, L, can be expressed as follows:
L=2πR (12)
The phase change experienced by an optical signal propagating around the resonator ring 342 can be tuned by the wavelength-tuning element 344 to shift the center wavelength of the resonance for the effective transfer function of the tunable RR filter 338. In some embodiments, the tunable RR filter 338 is configured to allow the center wavelength of the effective transfer function of the tunable RR filter to be swept across substantially the entire C band spectrum.
In some embodiments, the wavelength-tuning element 344 is implemented with a thermo-optical phase shifter or carrier injection optical phase shifter.
Referring again to Equation 4, it has been shown that the FSR of an RR filter can be calculated by the total length of the ring (including the coupler(s) and the ring). In some embodiments, the tunable RR filter 338 may be configured with an FSR of 30 nm to cover the full C band spectrum. In some embodiments, the total length of the tunable RR filter 338 may be in the range of 10-20 micrometers in order to provide an FSR large enough to cover substantially the whole C band spectrum.
Similar to the tunable optical filter 316 shown in
In the illustrated example, the tunable RR filter 368 includes a resonator ring 372 and a variable optical coupler 370 optically coupling the resonator ring 372 to the first optical path 364. The resonator ring 372 includes a wavelength-tuning element 374. The variable optical coupler 370 of the tunable RR filter 368 is based on a MZI structure that includes a third optical coupler 376, a fourth optical coupler 378, a third optical path 380 and a fourth optical path 382. The third optical coupler 376 has a first optical input port optically connected to one end of an optical waveguide of the resonator ring 372, a second optical input port optically connected to the first optical output port of the first optical coupler 360, a first optical output port optically connected to the third optical path 380, and a second optical output port optically connected to the fourth optical path 382. The fourth optical coupler 378 has a first optical input port optically connected to the third optical path 380, a second optical input port optically connected to the fourth optical path 382, a first optical output port optically connected to an opposite end of the optical waveguide of the resonator ring 372, and a second optical output port optically connected to the first optical input port of the second optical coupler 362. The fourth optical path 382 includes a controllable optical phase shifter 384.
In operation, a pass optical input signal is received at the pass optical input port 322 and is coupled onto the first and second optical paths 364 and 366 by the first optical coupler 360. An add optical input signal is received at the add optical input port 314. The add optical input signal may include one or more channel wavelengths in a third wavelength band. The tunable RR filter 368 is tunable to filter an optical signal propagating through the first optical path 364 to cause a portion of the pass optical input signal in the second wavelength band, to be passed from the pass optical input port 322 to the outgoing optical output port 308, and to cause a portion of the add optical input signal in the third wavelength band to be added to an outgoing optical output signal at the outgoing optical output port 308.
In some embodiments, the first and second tunable filters 316 and 318 are configured to have the third wavelength band, e.g., the Add wavelength band, at least partially overlap with the first wavelength band, e.g. the Drop wavelength band.
It is noted that the implementation and operation of the controllable optical phase shifters 386 and 384 and the tunable RR filter 368 shown in
Referring again to
The demultiplexer 500 has a drop optical input port 502 and eight local drop optical output ports 504. In the illustrated example, the demultiplexer includes seven 1×2 optical elements 506, 508, 510, 512, 514, 516 and 518 arranged in a cascade between the drop optical input port 502 and the local drop optical output ports 504.
In operation, the drop optical input port 502 receives a drop optical input signal, which may include a dropped first portion of an incoming optical signal in a first wavelength band. In some embodiments, the 1×2 optical elements 506, 508, 510, 512, 514, 516 and 518 may be implemented with 1×2 optical splitters, such as passive 1×2 optical splitters, which, in some cases, may be implemented using integrated silicon photonic MZI elements. In such embodiments, the 1×2 optical splitters distribute the dropped first portion of the incoming optical signal in the first wavelength band among the multiple local drop optical output ports 504. In other embodiments, the 1×2 optical elements 506, 508, 510, 512, 514, 516 and 518 may be implemented with 1×2 optical switches configured as variable splitters controllable to selectively distribute the dropped first portion of the incoming optical signal in the first wavelength band among the local drop optical output ports 504. For example, in some embodiments, the 1×2 optical switches may be controlled to selectively switch their respective optical input signal between one of their two outputs, while in other embodiments they may be controlled to split their respective optical input, possibly unequally, between their two optical outputs.
The multiplexer 520 has an add optical output port 522, eight local add optical input ports 524, and includes seven 2×1 optical combiners 526, 528, 530, 532, 534, 536 and 538 arranged in a cascade between the local add optical input ports 524 and the add optical output port 522. In some embodiments, the 2×1 optical combiners may be implemented using integrated silicon photonic MZI elements.
In operation, the local add optical input ports 524 receive local add optical input signals, which may be located in a third wavelength band. In some embodiments, the 2×1 optical elements 526, 528, 530, 532, 534, 536 and 538 may be implemented with 2×1 optical combiners, such as passive 2×1 optical combiners. In such embodiments, the 2×1 optical combiners combine the local add optical input signals from the local add optical input ports 524 into an add optical input signal at the add optical output port 522. In other embodiments, the 2×1 optical elements 526, 528, 530, 532, 534, 536 and 538 may be implemented with 2×1 optical switches configured as variable combiners controllable to selectively combine the local add optical input signals in the third wavelength band from the multiple local add optical input ports into the add optical input signal. For example, in some embodiments, the 2×1 optical switches may be controlled to select between their respective optical inputs, while in other embodiments they may be controlled to combine, possibly unequally, their respective optical inputs.
While the demultiplexer 500 and the multiplexer 520 each have eight local ports in the illustrated example depicted in
The demultiplexer 700 has a drop optical input port 702 and M local drop optical output ports 704. The demultiplexer 700 includes M three-port tunable optical filters 7061, 7062, 7063 . . . 706M arranged in a cascade 708. The first tunable optical filter 7061 in the cascade 708 has an optical input port optically connected to the drop optical input port 702, an optical output port optically connected to an optical input port of the next tunable optical filter 7062 in the cascade 708, and a drop optical output port optically connected to the first local drop optical output port. Each successive tunable optical filter in the cascade 708 has an optical input port optically connected to the optical output port of a preceding tunable optical filter in the cascade, an optical output port optically connected to a succeeding tunable optical filter in the cascade (with the exception of the last tunable optical filter in the cascade), and a drop optical output port optically connected to a respective local drop optical output port.
In operation, the first tunable optical filter 7061 in the cascade 708 receives a drop optical input signal, which may include a dropped first portion of an incoming optical signal in a first wavelength band, and each tunable optical filter in the cascade 708 is tunable to drop a respective portion of the drop optical input signal to a respective local drop optical output port of the M local drop optical output ports 704 and to pass a remaining portion onto the next tunable optical filter in the cascade 708.
In some embodiments, each tunable optical filter 7061, 7062, 7063, . . . , 706M in the cascade 708 is wavelength-tunable to drop a respective channel wavelength in the first wavelength band.
The multiplexer 710 has an add optical output port 712 and N local add optical input ports 714. The multiplexer 710 includes N tunable optical filters 7161, 7162, 7163 . . . 706N arranged in a cascade 718. The first tunable optical filter 7161 in the cascade 718 has an add optical input port optically connected to a respective local add optical input port of the N local add optical input ports 714, and an optical output port optically connected to the next tunable optical filter 7162 in the cascade 718. Each successive tunable optical filter in the cascade 718 has an optical input port optically connected to the optical output port of a preceding tunable optical filter in the cascade 718, an add optical input port optically connected to a respective local add optical input port of the N local add optical input ports 714, and an optical output port optically connected to a succeeding tunable optical filter in the cascade, with the exception of the last tunable optical filter 716N, which instead has its optical output port optically connected to the add optical output port 712.
In operation, the local add optical input ports 714 receive local add optical input signals, which may be located in a third wavelength band. Each tunable optical filter 7161, 7162, 7163, . . . , 716N in the cascade 718 is tunable to add a respective local add optical input signal in a third wavelength band from its respective local add optical input port to an optical signal received from the previous tunable optical filter in the cascade 718 and output the result to the next tunable optical filter in the cascade 718, with the last tunable optical filter 716N in the cascade 718 outputting its resulting optical output signal to the add optical output port 712.
In some embodiments, each tunable optical filter 7161, 7162, 7163, . . . , 716N in the cascade 718 is wavelength-tunable to add a respective channel wavelength in the third wavelength band.
In some embodiments, there are an equal number of local add ports 714 and local drop ports 704, i.e. N=M, while in other embodiments there are an unequal number of local add ports 714 and local drop ports 704, i.e. N≠M, with N being less than M in some cases, while in others N is greater than M.
In some embodiments, the tunable optical filters 7061 to 706M of the demultiplexer 700 may be implemented with MZI/RR hybrid optical filter structures similar to that of the three-port tunable optical filter 316 shown in
Similarly, in some embodiments, the tunable optical filters 7161 to 716M of the multiplexer 710 may be implemented with MZI/RR hybrid optical filter structures similar to that of the three-port tunable optical filter 318 shown in
The demultiplexer and multiplexer structure 850 has a drop optical input port 852, an add optical output port 854, P local drop optical output ports 8561, 8562, 8563, . . . 856P, and P local add optical input ports 8581, 8582, 8583, . . . , 858P. The demultiplexer and multiplexer structure 850 includes P six-port tunable optical filters 8601, 8602, 8603 . . . 860P arranged in a cascade 862.
The last six-port tunable optical filter 860P in the cascade 862 has a first optical input port In1 optically connected to the drop optical input port 852, a first optical output port Out1 optically connected to a first optical input port of the previous tunable optical filter in the cascade 862, a second optical input port In2 optically connected to a second optical output port of the previous tunable optical filter in the cascade 862, a second optical output port Out2 optically connected to the add optical output port 854, a drop optical output port Drop optically connected to the last local drop optical output port 856P, and an add optical input port Add optically connected to the last local add optical input port 858P.
Similarly, each preceding tunable optical filter in the cascade 862, with the exception of the first tunable optical filter 8601, has a first optical input port In1 optically connected to the first optical output port of the next tunable optical filter in the cascade 862, a first optical output port Out1 optically connected to a first optical input port of the previous tunable optical filter in the cascade 862, a second optical input port In2 optically connected to the second optical output port of the previous tunable optical filter in the cascade 862, a second optical output port Out2 optically connected to the second optical input port of the next tunable optical filter in the cascade 862, a drop optical output port Drop optically connected to a respective local drop optical output port, and an add optical input port Add optically connected to a respective local add optical input port. The first tunable optical filter 8601 in the cascade has the first optical input port In1 and the second optical output port Out2, but omits the first optical output port Out1 and the second optical input port In1.
In operation, the first optical input port In1 of the last tunable optical filter 860P in the cascade 862 receives a drop optical input signal from the drop optical input port 852. The drop optical input signal may include a dropped first portion of an incoming optical signal in a first wavelength band. Each tunable optical filter in the cascade 862 is tunable to drop a respective portion of the drop optical input signal to a respective local drop optical output port of the P local drop optical output ports and to pass a remaining portion onto the first optical input In1 of the next tunable optical filter in the cascade 862. Similarly, the tunable optical filters 8601, 8602, 8603, . . . , 860P may receive local add optical input signals from the local add optical input ports 8581, 8582, 8583, . . . , 858P. The local add optical input signals may be located in a third wavelength band. Each tunable optical filter 8601, 8602, 8603, . . . , 860P in the cascade 862 is tunable to add a respective local add optical input signal in a third wavelength band from its respective local add optical input port to an optical signal received via its second optical input port In2 from the previous tunable optical filter in the cascade 862 and to output the result to its second optical output port Out2, with the last tunable optical filter 860P in the cascade 862 outputting its resulting optical output signal to the add optical output port 854.
This architecture shares the same filtering for Add and Drop purposes, and hence reduces the total number of filtering modules employed in the AON architecture. This architecture also potentially provides colorless-directionless-contentionless (CDC) functionality (for a two degree optical node) with potentially no channel size/bandwidth limitations. Each tunable filter module can potentially be tuned to desired wavelengths/band to be added/dropped. It can therefore support colorless functionality and also potentially provides the ability to adjust the power level while dropping/adding channels.
In some embodiments, each tunable optical filter 8601, 8602, 8603, . . . , 860P in the cascade 862 is wavelength-tunable to drop a respective channel wavelength in the first wavelength band.
In some embodiments, each tunable optical filter 8601, 8602, 8603, . . . , 860P in the cascade 862 is wavelength-tunable to add a respective channel wavelength in the third wavelength band.
In the embodiment depicted in
The six-port tunable optical filter structure 900 has a first optical input port In1, a first optical output port Out1, a second optical input port In2, a second optical output port Out2, a drop optical output port Drop, and an add optical input port Add. The six-port tunable optical filter structure 900 includes two three-port tunable optical filters 902 and 904. The first three-port tunable optical filter 902 has an optical input port optically connected to the first optical input port In1, a first optical output port optically connected to the first optical output port Out1, and a second optical output port optically connected to the drop optical output port Drop. Similarly, the second three-port tunable optical filter 904 has a first optical input port optically connected to the second optical input port In2, a second optical input port optically connected to the add optical input port Add, and an optical output port optically connected to the second optical output port Out2.
In operation, for an optical signal received at the first optical input port In1, the first three-port tunable optical filter 902 is controllable to drop a respective portion of the optical signal in the first wavelength band to the local drop optical output port Drop and to pass a second portion of the optical signal to the first optical output port Out1. Similarly, the second three-port tunable optical filter 904 is controllable to add a respective local add optical input signal in a third wavelength band from the local add optical input port Add to an optical signal received at the second optical input port In2 and to output the result to the second optical output port Out2.
It is noted that the three-port tunable optical filters 902 and 904 may be implemented with MZI/RR hybrid filter structures such as the MZI/RR hybrid optical filter structures 316 and 318 shown in
In some embodiments, the three-port tunable optical filters 902 and 904 are tunable in terms of bandwidth, center wavelength, or both.
The three-port tunable optical filters 902 and 904 may be implemented in a silicon photonics fabrication technology in some embodiments.
It is noted that the example multiplexers and demultiplexers shown in
While
For example, in some embodiments passive splitters may be used for multiplexing and/or demultiplexing. In such embodiments, local add channels may be combined by a cascade of passive splitter functioning as passive combiners and fed into an add optical output port and vice versa for local drop channels. In some cases, the use of passive splitters/combiners may need amplifications which can be provided either before or after the local Add/Drop multiplexing and demultiplexing section of the AON node apparatus (independent of pass/transit channels). This type of solution may be well suited for implementations with a limited number of local add and drop ports and can potentially be implemented at a relatively low cost. In addition, colorless functionality can be supported.
In other embodiments, the multiplexing and demultiplexing functionality for local add and drop channels is implemented with an Array Wave Guide (AWG) based structure, with a first AWG for demultiplexing local drop channels and a second AWG for multiplexing local add channels. In this type of structure, insertion loss is potentially reduced compared to the passive splitter/combiner structure described above, but the structure is not colorless.
In still other embodiments, a photonic integrated circuit (PIC) switch fabric may be included after an AWG based structure that includes a first AWG for demultiplexing local drop channels and a second AWG for multiplexing local add channels. The addition of the PIC switch fabric allows the resulting structure to potentially support colorless functionality since the outputs of the two AWGs can potentially be selectively switched among the available add and drop ports through the PIC switch fabric. However, this colorless functionality comes at the potential expense of some increased insertion loss and/or potential control challenges.
An example ring network that includes AON optical nodes according to an embodiment of the present invention will now be discussed with reference to
The optical waveguides 1010, 1012, 1014 and 1016 may be implemented with any type of optical waveguide medium. In some embodiments, one or more of the optical waveguides 1010, 1012, 1014 and 1016 may be implemented with optical fiber.
For illustrative purposes,
The optical node 1004 is configured to receive the outgoing optical output signal as an incoming optical input signal at its Incoming optical port, to drop a first portion of the incoming optical input signal containing the channel wavelengths/band 1020 to its local Drop output port, and to pass a second portion of the incoming optical input signal containing the channel wavelengths/bands 1022 and 1024 to its Outgoing optical output port as part of an outgoing optical output signal. The outgoing optical output signal containing the channel wavelengths/bands 1022 and 1024 propagates over optical waveguide 1012 to the Incoming optical input port of the optical node 1006.
The optical node 1006 is configured to receive the outgoing optical output signal as an incoming optical input signal at its Incoming optical port, to drop a first portion of the incoming optical input signal containing the channel wavelengths/band 1022 to its local Drop output port, and to pass a second portion of the incoming optical input signal containing the channel wavelengths/band 1024 to its Outgoing optical output port as part of an outgoing optical output signal. The outgoing optical output signal containing the channel wavelengths/band 1024 propagates over optical waveguide 1014 to the Incoming optical input port of the optical node 1008.
The optical node 1008 is configured to receive the outgoing optical output signal as an incoming optical input signal at its Incoming optical port and to drop a first portion of the incoming optical input signal containing the channel wavelengths/band 1024 to its local Drop output port.
Note that in the illustrated example, optical node 1002 can use any channel wavelength in channel wavelengths/band 1022 to directly communicate with optical node 1006 because optical node 1004 is configured with a pass band that includes the channel wavelengths/band 1022. That is, the optical node 1004 can be said to be “transparent” to the channel wavelengths/band 1022. As noted earlier with reference to Equation 9, by utilizing tunable optical filtering to implement ADM functionality according to an embodiment of the present invention, there is a trade-off between losses incurred by incoming transit/pass channel wavelengths/bands and local add and drop channels wavelengths/bands. For the purposes of link budget optimization it may be desirable to exploit this trade-off so that losses experienced in the transit/pass band are reduced or minimized in trade for increased losses incurred by locally added/dropped channels.
As will be appreciated, although
While
Example apparatuses and structures to support bi-directional or two degree ADM functionality will now be discussed with reference to
Similar to the apparatus 100 shown in
For illustrative purposes the first and second directions are designated as “East” and “West”, respectively, in
In operation, to implement drop functionality for the first direction, the Incoming optical input port of the first tunable optical filter 1102 receives an incoming optical signal from the first direction (East) and the first tunable optical filter 1102 is controllable to drop a first portion of the incoming optical signal in a first wavelength band for the first direction to its Drop optical output port and to pass a second portion of the incoming optical signal in a second wavelength band for the second direction to its Outgoing optical output port. The first drop demultiplexer 1106 distributes the dropped first portion of the incoming optical signal in the first wavelength band for the first direction among the local drop optical output ports 1116. To implement add functionality for the second direction (West), the first add multiplexer 1108 is configured to combine local add optical input signals in a third wavelength band for the second direction from the local add optical input ports 1118 into an add optical input signal for the second direction, and the first tunable optical filter 1102 is configured to add the add optical input signal for the second direction to an outgoing optical signal for the second direction at its Outgoing optical output port.
Similarly, to implement drop functionality for the second direction, the Incoming optical input port of the second tunable optical filter 1104 receives an incoming optical signal from the second direction (West) and the second tunable optical filter 1104 is controllable to drop a first portion of the incoming optical signal in a first wavelength band for the second direction to its Drop optical output port and to pass a second portion of the incoming optical signal in a second wavelength band for the first direction to its Outgoing optical output port. The second drop demultiplexer 1110 distributes the dropped first portion of the incoming optical signal in the first wavelength band for the second direction among the local drop optical output ports 1120. To implement add functionality for the first direction, the second add multiplexer 1112 is configured to combine local add optical input signals in a third wavelength band for the first direction from the local add optical input ports 1122 into an add optical input signal for the first direction, and the second tunable optical filter 1104 is configured to add the add optical input signal for the first direction to an outgoing optical signal for the first direction at its Outgoing optical output port.
The tunable optical filters 1102 and 1104, the drop demultiplexers 1106 and 1110, and the add multiplexers 1108 and 1112 may be implemented in a silicon photonics fabrication technology in some embodiments.
As in other embodiments, each of the tunable optical filters 1102 and 1104, the drop demultiplexers 1106 and 1110, and the add multiplexers 1108 and 1112 may be tunable in terms of bandwidth, center wavelength, or both.
In some embodiments, the first tunable optical filter 1102 is configured so that the third wavelength band for the second direction and the first wavelength band for the first direction are non-overlapping. In other embodiments, the first tunable optical filter 1102 is configured so that the third wavelength band for the second direction and the first wavelength band for the first direction at least partially overlap. Similarly, in some embodiments, the second tunable optical filter 1104 is configured so that the third wavelength band for the first direction and the first wavelength band for the second direction are non-overlapping. In other embodiments, the second tunable optical filter 1104 is configured so that the third wavelength band for the first direction and the first wavelength band for the second direction at least partially overlap.
It will be appreciated that, in some embodiments, each of the tunable optical filters 1102 and 1104 may be implemented with structures such as those shown in
In some embodiments, the components that provide the add, drop and/or pass through functionality of the apparatuses described herein may be integrated into a single module. In other embodiments, some of the components may be implemented as separate modules that may be optically coupled together by optical fiber or some other form of optical waveguide to form the apparatus.
For example, with reference to
Implementing the apparatuses in a modular manner as described above can provide flexibility in terms of configurability when initially deploying the apparatus in an optical node, as well as potentially allowing re-configurability to accommodate future upgrades and/or changing network needs. For example, an apparatus may be initially deployed with an add multiplexer module for one degree based on a power splitter architecture that can later be replaced with an add multiplexer module based on a cascade of tunable optical filters, such as the add multiplexer 710 shown in
Each of the optical nodes 1202, 1204, 1206 and 1208 has an Add optical input port, a Drop optical output port, an Outgoing optical output port and an Incoming optical input port for each of two directions (clockwise and counter clockwise in the illustrated example).
The Outgoing optical output port of the optical node 1202 for the clockwise direction is optically connected to the Incoming optical input port of optical node 1204 for the clockwise direction through an optical waveguide 1210. The Outgoing optical output port of the optical node 1204 for the clockwise direction is optically connected to the Incoming optical input port of optical node 1206 for the clockwise direction through an optical waveguide 1212. The Outgoing optical output port of the optical node 1206 for the clockwise direction is optically connected to the Incoming optical input port of optical node 1208 for the clockwise direction through an optical waveguide 1214. The Outgoing optical output port of the optical node 1208 for the clockwise direction is optically connected to the Incoming optical input port of optical node 1202 for the clockwise direction through an optical waveguide 1216.
In the counter clockwise direction, the Outgoing optical output port of the optical node 1202 for the counter clockwise direction is optically connected to the Incoming optical input port of optical node 1208 for the counter clockwise direction through an optical waveguide 1217. The Outgoing optical output port of the optical node 1208 for the counter clockwise direction is optically connected to the Incoming optical input port of optical node 1206 for the counter clockwise direction through an optical waveguide 1215. The Outgoing optical output port of the optical node 1206 for the counter clockwise direction is optically connected to the Incoming optical input port of optical node 1204 for the counter clockwise direction through an optical waveguide 1213. The Outgoing optical output port of the optical node 1204 for the counter clockwise direction is optically connected to the Incoming optical input port of optical node 1202 for the counter clockwise direction through an optical waveguide 1211.
The optical waveguides 1210, 1211, 1212, 1213, 1214, 1215, 1216 and 1217 may be implemented with any type of optical waveguide medium. In some embodiments, one or more of the optical waveguides 1210, 1211, 1212, 1213, 1214, 1215, 1216 and 1217 may be implemented with optical fiber.
For illustrative purposes,
In the clockwise direction, the outgoing optical output signal containing the channel wavelengths/bands 1220 and 1222 propagates in the clockwise direction around the ring 1200 over optical waveguide 1210 to the Incoming optical input port of the optical node 1204 for the clockwise direction.
The optical node 1204 is configured to receive the outgoing optical output signal as an incoming optical input signal at its Incoming optical port for the clockwise direction, to drop a first portion of the incoming optical input signal containing the channel wavelengths/band 1220 to its local Drop output port Drop1 for the clockwise direction, and to pass a second portion of the incoming optical input signal containing the channel wavelengths/bands 1222 to its Outgoing optical output port for the clockwise direction as part of an outgoing optical output signal for the clockwise direction. The outgoing optical output signal containing the channel wavelengths/bands 1222 propagates in the clockwise direction of the optical ring 1200 over optical waveguide 1212 to the Incoming optical input port of the optical node 1206 for the clockwise direction.
The optical node 1206 is configured to receive the outgoing optical output signal as an incoming optical input signal at its Incoming optical port for the clockwise direction and to drop a first portion of the incoming optical input signal containing the channel wavelengths/band 1222 to its local Drop output port Drop1 for the clockwise direction.
In the counter clockwise direction, the outgoing optical output signal containing the channel wavelengths/band 1224 propagates in the counter clockwise direction around the ring 1200 over optical waveguide 1217 to the Incoming optical input port of the optical node 1208 for the counter clockwise direction.
The optical node 1208 is configured to receive the outgoing optical output signal as an incoming optical input signal at its Incoming optical port for the counter clockwise direction and to drop a first portion of the incoming optical input signal containing the channel wavelengths/band 1224 to its local Drop output port Drop2 for the counter clockwise direction.
Note that in the illustrated example, optical node 1202 can use any channel wavelength in channel wavelengths/band 1222 to directly communicate with optical node 1206 because optical node 1204 is configured with a pass band that includes the channel wavelengths/band 1222. However, due to the bi-directional functionality of the optical ring network 1200, rather than having to communicate with optical node 1208 through optical nodes 1204 and 1206, the optical node 1202 may instead communicate directly with optical node 1208 in the counter clockwise direction of the optical ring 1200, thereby reducing the path length and potentially the losses incurred.
As will be appreciated, although
Moreover, although the example optical ring networks 1000 and 1200 depicted in
Although
In the optical network 1300, the optical nodes 1310, 1312, 1314, 1316, 1318, 1320 and 1322 are optically interconnected such that the optical nodes optical nodes 1310, 1312, 1314, 1316, 1318 and 1320 are bi-directionally connected in a ring topology, but the optical node 1322 is bi-directionally connected between the optical nodes 1312 and 1318. As such, the optical nodes 1318 and 1312 are three degree nodes, while the optical nodes 1310, 1314, 1316, 1320 and 1322 are two degree nodes.
The optical node 1322 may be implemented with bi-directional ADM functionality as described above in order to allow the optical nodes 1312 and 1318 to communicate directly through channel wavelengths/bands in the pass band of the optical node 1322, while also allowing channels to be locally added and/or dropped in either direction.
It will be appreciated that such functionality may not only be useful in “bridging” an otherwise ring shaped network, as depicted in
The example method 1400 is illustrative of one embodiment. In other embodiments, similar or different operations could be performed in a similar or different order. Various ways to perform the illustrated operations, as well as examples of other operations that may be performed, are described herein. Further variations may be or become apparent.
For example, in some embodiments, controlling the tunable optical filter at 1402 involves configuring the tunable optical filter to lower an optical loss in the passed second portion of the incoming optical signal in the second wavelength band at the account of a corresponding increase of an optical loss in the dropped first portion of the incoming optical signal in the first wavelength band.
In some cases, controlling the tunable optical filter at 1402 involves wavelength-tuning the tunable optical filter to adjust a center wavelength of the first wavelength band, bandwidth-tuning the tunable optical filter to adjust bandwidth of the first wavelength band, or both.
In order to provide add functionality, the method 1400 may further include combining local add optical input signals in a third wavelength band into an add optical input signal and controlling the tunable optical filter to add the add optical input signal to the passed second portion of the incoming optical signal in the second wavelength band.
In some implementations, the tunable optical filter may be implemented with two three-port tunable optical filters. In such implementations, controlling the tunable optical filter at 1402 may include controlling a first three-port tunable optical filter to drop the first portion of the incoming optical signal in the first wavelength band and pass the second portion of the incoming optical signal in the second wavelength band, and controlling a second three-port tunable optical filter to add the add optical input signal in the third wavelength band to the passed second portion of the incoming optical signal in the second wavelength band. In some such cases, controlling the first three-port tunable optical filter involves configuring the first three-port tunable optical filter to lower an optical loss in the passed second portion of the incoming optical signal in the second wavelength band at the account of a corresponding increase of an optical loss in the dropped first portion of the incoming optical signal in the first wavelength band. Similarly, controlling the second three-port tunable optical filter may involve configuring the second three-port tunable optical filter to lower an optical loss in the passed second portion of the incoming optical signal in the second wavelength band at the account of a corresponding increase of an optical loss in the add optical input signal in the third wavelength band.
In some implementations, distributing the dropped first portion of the incoming optical signal in the first wavelength band among local drop optical output ports at 1404 involves controlling multiple of tunable optical filters arranged in a cascade. For example, each tunable optical filter in the cascade may be operable to drop a respective portion of the dropped first portion of the incoming optical signal to a respective local drop optical output port. In some such embodiments, controlling the multiple tunable optical filters arranged in the cascade involves wavelength-tuning one or more of the tunable optical filters to each drop a respective channel wavelength in the first wavelength band.
Similarly, in those embodiments in which the method 1400 further includes combining local add optical input signals in the third wavelength band into the add optical input signal, such combining may involve controlling multiple tunable optical filters arranged in a cascade. For example, each tunable optical filter in the cascade may be tunable to add a respective local add optical input signal from a respective local add optical input port into the add optical input signal. In some such embodiments, controlling the multiple tunable optical filters arranged in the cascade involves wavelength-tuning one or more of the tunable optical filters to each add a respective channel wavelength in the third wavelength band.
Methods as disclosed herein could be performed or implemented at an optical network node for all optical networking.
Numerous modifications and variations of the present application are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the application may be practised otherwise than as specifically described herein.
In addition, although described primarily in the context of methods, apparatus and equipment, other implementations are also contemplated, such as in the form of instructions stored on a non-transitory computer-readable medium, for example.