Subchannel photonic routing, switching and protection with simplified upgrades of WDM optical networks
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H04J-014/02
H04B-010/572
출원번호
US-0961432
(2010-12-06)
등록번호
US-9485050
(2016-11-01)
발명자
/ 주소
Barnard, Chris Wilhelm
Mylinski, Piotr
출원인 / 주소
Treq Labs, Inc.
대리인 / 주소
Blakely Sokoloff Taylor & Zafman LLP
인용정보
피인용 횟수 :
2인용 특허 :
143
초록▼
The present invention includes novel techniques, apparatus, and systems for optical WDM communications. Tunable lasers are employed to generate respective subcarrier frequencies which represent subchannels of an ITU channel to which client signals can be mapped. In one embodiment, subchannels are po
The present invention includes novel techniques, apparatus, and systems for optical WDM communications. Tunable lasers are employed to generate respective subcarrier frequencies which represent subchannels of an ITU channel to which client signals can be mapped. In one embodiment, subchannels are polarization interleaved to reduce crosstalk. In another embodiment, polarization multiplexing is used to increase the spectral density. Client circuits can be divided and combined with one another before being mapped, independent of one another, to individual subchannels within and across ITU channels. A crosspoint switch can be used to control the client to subchannel mapping, thereby enabling subchannel protection switching and hitless wavelength switching. Network architectures and subchannel transponders, muxponders and crossponders are disclosed, and techniques are employed (at the subchannel level/layer), to facilitate the desired optical routing, switching, concatenation and protection of the client circuits mapped to these subchannels across the nodes of a WDM network.
대표청구항▼
1. An optical subchannel muxponder that can transmit optical signals among a plurality of nodes interconnected by one or more fiber optic cables to form an optical network, the optical subchannel muxponder comprising: (a) a subchannel mapper that can map each of a plurality of client signals to a co
1. An optical subchannel muxponder that can transmit optical signals among a plurality of nodes interconnected by one or more fiber optic cables to form an optical network, the optical subchannel muxponder comprising: (a) a subchannel mapper that can map each of a plurality of client signals to a corresponding subchannel within or across a plurality of ITU channels, wherein each ITU channel in the plurality of ITU channels has a predefined ITU frequency and a corresponding plurality of subchannels, and wherein each subchannel has an associated frequency with a predetermined offset from the predefined ITU frequency of the subchannel's corresponding ITU channel;(b) one or more lasers that can be tuned to generate modulated client signals at frequencies associated with each subchannel;(c) a multiplexer that can combine the modulated client signals for transmission onto the fiber optic cables of the optical network; and(d) either (i) a client signal multiplexer that can combine a plurality of client signals into a single higher-rate signal that can be mapped to a distinct subchannel, or (ii) a client signal inverse multiplexer that can divide a client signal having a data rate into a plurality of signals including a first signal that can be mapped to a subchannel of a first ITU channel, and a second signal that can be mapped to a subchannel of a second ITU channel different from the first ITU channel. 2. The optical subchannel muxponder of claim 1, further comprising: (a) a receiver that can receive an optical signal via the fiber optic cables of the optical network;(b) a demultiplexer that can filter the modulated client signals from the received optical signal;(c) a subchannel demodulator containing one or more optical detectors that can detect and isolate the client signals from the modulated client signals associated with each subchannel; and(d) a subchannel demapper that can demap the demodulated client signals associated with each subchannel and return the demapped client signals to their respective client transceivers. 3. The optical subchannel muxponder of claim 2, further comprising a SERDES-FEC-SERDES block that can perform at least one of the following functions: (a) insert onto and extract from each client signal performance monitoring information;(b) add to and remove from each client signal channel overhead information for remote network management;(c) add to and remove from each client signal channel overhead information including the destination of the client signal; and(d) encode and decode client signal data for forward error correction. 4. The optical subchannel muxponder of claim 1, wherein the subchannel mapper contains a crossconnect switch that can map each of the plurality of client signals to the corresponding subchannel within or across the plurality of ITU channels. 5. The optical subchannel muxponder of claim 4, wherein the time required to map one of the plurality of client signals to the corresponding subchannel is substantially equivalent to the switching time of the crossconnect switch when the laser associated with the corresponding subchannel has previously been tuned to its associated frequency. 6. The optical subchannel muxponder of claim 1, wherein a first modulation format is employed to generate a first modulated client signal and a second modulation format is employed to generate a second modulated client signal, and wherein each of the first and second modulated client signals can be mapped to the corresponding subchannel within or across the plurality of ITU channels. 7. The optical subchannel muxponder of claim 2, further comprising independent clock recovery and clock multiplier circuitry with respect to each subchannel to support clock independence among the plurality of client signals. 8. The optical subchannel muxponder of claim 1, wherein the sub channel mapper can map each of a first client signal employing a first data protocol and a second client signal employing a second data protocol to the corresponding subchannel within or across the plurality of ITU channels. 9. The optical subchannel muxponder of claim 1, wherein each subchannel has a distinct corresponding laser that can be tuned to generate a modulated client signal at the frequency associated with the subchannel. 10. The optical subchannel muxponder of claim 1, further comprising a polarization combiner that can transmit adjacent subchannels with orthogonal polarizations. 11. The optical subchannel muxponder of claim 1, wherein the relative power levels of transmitters associated with each subchannel are adjusted to optimize overall optical performance of the subchannels. 12. The optical subchannel muxponder of claim 1, wherein the frequencies of the subchannel lasers are fine-tuned to optimize overall optical performance of the subchannels. 13. A system for multiplexing, transmitting and demultiplexing polarization-multiplexed signals, the system comprising: (a) a polarization combiner that combines a first set of signals aligned along a first linear polarization axis with a second set of signals aligned along a second linear polarization axis, wherein the first and second polarization axes are orthogonally polarized;(b) a transmitting medium which can modify polarization states of the first and second sets of signals, but will maintain orthogonality of the polarization between the sets of signals;(c) a polarization tracker that receives a plurality of transmitted signals from the first and second sets of signals, and modifies the polarization states of the received signals to transform the polarization state of the first set of signals to a first output linear polarization axis, and correspondingly transform the polarization state of the second set of signals to a second output linear polarization axis that is orthogonal to the first output linear polarization axis;(d) a polarization beam splitter at the output of the polarization tracker with one of its output linear polarization axes aligned with the first output polarization axis of the polarization tracker, and the other output polarization axis aligned with the second output polarization axis of the polarization tracker;(e) feedback circuitry that monitors and analyzes one or both outputs of the polarization beam splitter, and provides a control signal back to the polarization tracker to align the signal polarizations of the first set of signals with the first polarization axis of the polarization beam splitter, and to align the signal polarizations of the second set of signals with the second polarization axis of the polarization beam splitter;(f) at least one optical filter at the output of each branch of the polarization beam splitter that demultiplexes the signals in each linear polarization; and(e) a client signal inverse multiplexer that divides a client signal having a data rate into a plurality of signals each having data rates lower than the date rate of the client signal, the plurality of signals including the first set of signals and the second set of signals, wherein a first signal from the first set of signals is mapped to a subchannel of a first ITU channel, and a second signal from the second set of signals is mapped to a subchannel of a second ITU channel different from the first ITU channel. 14. The system of claim 13, wherein the first and second set of signals can be transmitted to a first node of an optical network, and wherein the polarization axes of a third set of signals added at the first node have the same polarization alignment as the first set of signals, and the polarization axes of a fourth set of signals added at the first node have the same polarization alignment as the second set of signals. 15. The system of claim 13 wherein low-frequency dither signals are applied to the first and second set of signals to enable narrow-band detection of the signal amplitudes in one or both outputs of the polarization beam splitter. 16. The system of claim 13, further comprising circuitry that monitors the total received power of the first and second set of signals, and a variable gain amplifier that adjusts the control signal in response to changes in the total received power. 17. A method for transmitting optical signals among a plurality of nodes interconnected by one or more fiber optic cables to form an optical network, the method comprising the following steps: (a) mapping each of a plurality of client signals to a corresponding subchannel within or across a plurality of ITU channels, wherein each ITU channel in the plurality of ITU channels has a predefined ITU frequency and a corresponding plurality of subchannels, and wherein each subchannel has an associated frequency with a predetermined offset from the predefined ITU frequency of the subchannel's corresponding ITU channel;(b) tuning one or more lasers to generate modulated client signals at frequencies associated with each subchannel; and(c) combining the modulated client signals for transmission onto the fiber optic cables of the optical network; and(d) either (i) combining a plurality of client signals into a single higher-rate signal that can be mapped to a distinct subchannel, or (ii) dividing a client signal having a data rate into a plurality of signals each having data rates lower than the data rate of the client signal, the plurality of signals including a first signal that can be mapped to a subchannel of a first ITU channel, and a second signal that can be mapped to a subchannel of a second ITU channel different from the first ITU channel. 18. The method of claim 17, further comprising the following steps: (a) receiving an optical signal via the fiber optic cables of the optical network;(b) filtering the modulated client signals from the received optical signal;(c) demodulating the modulated client signals associated with each subchannel; and(d) demapping the demodulated client signals associated with each subchannel and returning the demapped client signals to their respective client transceivers. 19. The method of claim 18, further comprising at least one of the following steps: (a) inserting onto and extracting from each client signal performance monitoring information;(b) adding to and removing from each client signal channel overhead information for remote network management;(c) adding to and removing from each client signal channel overhead information including the destination of the client signal; and(d) encoding and decoding client signal data for forward error correction. 20. The method of claim 17, further comprising the step of mapping, via a crossconnect switch, each of the plurality of client signals to the corresponding subchannel within or across the plurality of ITU channels. 21. The method of claim 20, wherein the time required to map one of the plurality of client signals to the corresponding subchannel is substantially equivalent to the switching time of the crossconnect switch when the laser associated with the corresponding subchannel has previously been tuned to its associated frequency. 22. The method of claim 17, further comprising the following steps: (a) generating a first modulated client signal by employing a first modulation format;(b) generating a second modulated client signal by employing a second modulation format; and(c) mapping each of the first and second modulated client signals to the corresponding subchannel within or across the plurality of ITU channels. 23. The method of claim 18, further comprising the step of independently clocking the first and second client signals by employing independent clock recovery and clock multiplier circuitry with respect to each subchannel. 24. The method of claim 17, further comprising the step of mapping each of a first client signal employing a first data protocol and a second client signal employing a second data protocol to the corresponding subchannel within or across the plurality of ITU channels. 25. The method of claim 17, wherein each subchannel has a distinct corresponding laser that can be tuned to generate a modulated client signal at the frequency associated with the subchannel. 26. The method of claim 17, further comprising the step of employing a polarization combiner to transmit adjacent subchannels with orthogonal polarizations. 27. The method of claim 17, further comprising the step of adjusting the relative power levels of transmitters associated with each subchannel to optimize overall optical performance of the subchannels. 28. The method of claim 17, further comprising the step of fine-tuning the frequencies of the subchannel lasers to optimize overall optical performance of the subchannels. 29. A method for multiplexing, transmitting and demultiplexing polarization-multiplexed signals, the method comprising the following steps: (a) combining a first set of signals aligned along a first liner polarization axis with a second set of signals aligned along a second linear polarization axis, wherein the first and second polarization axes are orthogonally polarized;(b) launching the combined signals onto a transmitting medium which can modify polarization states of the first and second set of signals, but will maintain orthogonality of the polarization between the sets of signals;(c) receiving a plurality of transmitted signals from the first and second sets of signals, and modifying the polarization states of the received signals to transform the polarization state of the first set of signals to a first output linear polarization axis, and correspondingly transform the polarization state of the second set of signals to a second output linear polarization axis that is orthogonal to the first output linear polarization axis;(d) splitting the first set of signals aligned with the first output polarization axis from the second set of signals aligned with the second output polarization axis;(e) monitoring and analyzing one or both of the split sets of signals, and generating a control signal to align the signal polarizations of the first set of signals with the first output linear polarization axis, and to align the signal polarizations of the second set of signals with the second polarization axis; and(f) demultiplexing the signals in each linear polarization;(g) dividing a client signal having a data rate into a plurality of signals each having data rates lower than the data rates of the client signal, the plurality of signals including the first set of signals and the second set of signals; and(h) mapping a first signal from the first set of signals to a subchannel of a first ITU channel, and a second signal from the second set of signals to a subchannel of second ITU channel different from the first ITU channel. 30. The method of claim 29, further comprising the steps of transmitting the first and second set of signals to a first node of an optical network, wherein the polarization axes of a third set of signals added at the first node have the same polarization alignment as the first set of signals, and the polarization axes of a fourth set of signals added at the first node have the same polarization alignment as the second set of signals. 31. The method of claim 29, wherein low-frequency dither signals are applied to the first and second set of signals to enable narrow-band detection of the signal amplitudes in one or both of the split sets of signals. 32. The method of claim 29, further comprising the steps of monitoring the total received power of the first and second set of signals, and adjusting the control signal in response to changes in the total received power. 33. An optical subchannel muxponder that can transmit optical signals among a plurality of nodes interconnected by one or more fiber optic cables to form an optical network, the optical subchannel muxponder comprising: (a) a first plurality of lasers, each of which is tuned to generate a subfrequency at a predetermined offset from a first predefined ITU frequency, wherein the first predefined ITU frequency constitutes a first ITU channel and the subfrequencies constitute subchannels of the first ITU channel;(b) a second plurality of lasers, each of which is tuned to generate a subfrequency at a predetermined offset from a second predefined ITU frequency, wherein the second predefined ITU frequency constitutes a second ITU channel different from the first ITU channel and the subfrequencies constitute subchannels of the second ITU channel;(c) an inverse multiplexer that divides a client signal having a data rate into a plurality of signals each having data rates lower than the data rate of the client signal, the plurality of signals including a first signal that is mapped to a subchannel of the first ITU channel, and a second signal that is mapped to a subchannel of the second ITU channel;(d) a first modulator that modulates the first signal onto the subfrequency of the subchannel to which it is mapped, generating a first modulated subchannel signal of the first ITU channel;(e) a second modulator that modulates the second signal onto the subfrequency of the subchannel to which it is mapped, generating a second modulated subchannel signal of the second ITU channel; and(f) a multiplexer that combines the first and second modulated subchannel signals into an optical signal for transmission onto a fiber optic cable of the optical network. 34. The optical subchannel muxponder of claim 33, further comprising: (a) a receiver that can receive an optical signal via the fiber optic cables of the optical network;(b) a demultiplexer that can filter the modulated subchannel signals from the received optical signal; and(c) a subchannel demodulator containing one or more optical detectors that can detect and isolate the client signal from the modulated subchannel signals associated with each subchannel. 35. The optical subchannel muxponder of claim 34, further comprising a SERDES-FEC-SERDES block that can perform at least one of the following functions: (a) insert onto and extract from each modulated subchannel signal performance monitoring information;(b) add to and remove from each modulated subchannel signal channel overhead information for remote network management;(c) add to and remove from each modulated subchannel signal channel overhead information including the destination of the modulated subchannel signal; and(d) encode and decode modulated subchannel signal data for forward error correction. 36. The optical subchannel muxponder of claim 33, wherein each of the plurality of signals from the divided client signal can be mapped to a distinct subchannel in a data frame having frame markers that facilitate the reconstruction of the client signal. 37. The optical subchannel muxponder of claim 33, wherein each of the plurality of signals from the divided client signal can be mapped to a distinct subchannel. 38. The optical subchannel muxponder of claim 33, further comprising a crossconnect switch that can map each client signal to any available subchannel of any ITU channel. 39. The optical subchannel muxponder of claim 38, wherein the time required to map a client signal to an available subchannel is substantially equivalent to the switching time of the crossconnect switch when the laser associated with the available subchannel has previously been tuned to its associated frequency. 40. The optical subchannel muxponder of claim 33, wherein a first modulation format is employed to generate a first modulated subchannel signal and a second modulation format is employed to generate a second modulated subchannel signal. 41. The optical subchannel muxponder of claim 34, further comprising independent clock recovery and clock multiplier circuitry with respect to each subchannel to support clock independence among the subchannel signals. 42. The optical subchannel muxponder of claim 33, wherein each of a first client signal employing a first data protocol and a second client signal employing a second data protocol can be mapped to any available subchannel of any ITU channel. 43. The optical subchannel muxponder of claim 33, wherein each subchannel has a distinct corresponding laser that can be tuned to generate a modulated subchannel signal at the frequency associated with the subchannel. 44. The optical subchannel muxponder of claim 33, further comprising a polarization combiner that can transmit adjacent subchannels with orthogonal polarizations. 45. The optical subchannel muxponder of claim 33, wherein the relative power levels of transmitters associated with each subchannel are adjusted to optimize overall optical performance of the subchannels. 46. The optical subchannel muxponder of claim 33, wherein the frequencies of the subchannel lasers are fine-tuned to optimize overall optical performance of the subchannels. 47. A method for transmitting optical signals among a plurality of nodes interconnected by one or more fiber optic cables to form an optical network, the method comprising the following steps: (a) tuning each of a first plurality of lasers to generate a subfrequency at a predetermined offset from a first predefined ITU frequency, wherein the first predefined ITU frequency constitutes a first ITU channel and the subfrequencies constitute subchannels of the first ITU channel;(b) tuning each of a second plurality of lasers to generate a subfrequency at a predetermined offset from a second predefined ITU frequency, wherein the second predefined ITU frequency constitutes a second ITU channel different from the first ITU channel and the subfrequencies constitute subchannels of the second ITU channel;(c) dividing a client signal having a data rate into a plurality of signals each having data rates lower than the data rate of the client signal, the plurality of signals including a first signal that is mapped to a subchannel of the first ITU channel, and a second signal that is mapped to a subchannel of the second ITU channel;(d) modulating the first signal onto the subfrequency of the subchannel to which it is mapped, generating a first modulated subchannel signal of the first ITU channel;(e) modulating the second signal onto the subfrequency of the subchannel to which it is mapped, generating a second modulated subchannel signal of the second ITU channel; and(f) combining the first and second modulated subchannel signals into an optical signal for transmission onto a fiber optic cable of the optical network. 48. The method of claim 47, further comprising the following steps: (a) receiving an optical signal via the fiber optic cables of the optical network;(b) filtering the modulated subchannel signals from the received optical signal; and(c) demodulating the modulated subchannel signals associated with each subchannel. 49. The method of claim 48, further comprising at least one of the following steps: (a) inserting onto and extracting from each modulated subchannel signal performance monitoring information;(b) adding to and removing from each modulated subchannel signal channel overhead information for remote network management;(c) adding to and removing from each modulated subchannel signal channel overhead information including the destination of the modulated subchannel signal; and(d) encoding and decoding modulated subchannel signal data for forward error correction. 50. The method of claim 47, wherein each of the plurality of signals from the divided client signal can be mapped to a distinct subchannel in a data frame having frame markers that facilitate the reconstruction of the client signal. 51. The method of claim 47, further comprising the step of combining a plurality of client signals into a single higher-rate signal that can be mapped to a distinct subchannel. 52. The method of claim 47, further comprising the step of mapping, via a crossconnect switch, each of a plurality of client signals to any available subchannel of any ITU channel. 53. The method of claim 52, wherein the time required to map a client signal to an available subchannel is substantially equivalent to the switching time of the crossconnect switch when the laser associated with the available subchannel has previously been tuned to its associated frequency. 54. The method of claim 47, further comprising the following steps: (a) generating a first modulated subchannel signal by employing a first modulation format;(b) generating a second modulated subchannel signal by employing a second modulation format; and(c) mapping each of the first and second modulated subchannel signals to any available subchannel of any ITU channel. 55. The method of claim 48, further comprising the step of independently clocking the first and second subchannel signals by employing independent clock recovery and clock multiplier circuitry with respect to each subchannel. 56. The method of claim 47, further comprising the step of mapping each of a first client signal employing a first data protocol and a second client signal employing a second data protocol to any available subchannel of any ITU channel. 57. The method of claim 47, wherein each sub channel has a distinct corresponding laser that can be tuned to generate a modulated subchannel signal at the frequency associated with the subchannel. 58. The method of claim 47, further comprising the step of employing a polarization combiner to transmit adjacent subchannels with orthogonal polarizations. 59. The method of claim 47, further comprising the step of adjusting the relative power levels of transmitters associated with each subchannel to optimize overall optical performance of the subchannels. 60. The method of claim 47, further comprising the step of fine-tuning the frequencies of the subchannel lasers to optimize overall optical performance of the subchannels.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (143)
Egnell, Lars, Add and drop node for an optical WDM network having traffic only between adjacent nodes.
Stamatios Vasilios Kartalopoulos, Add/drop capability for ultra-high speed dense wavelength division multiplexed systems using a wavelength bus architecture.
Hietala Vincent M. (Placitas NM) Kravitz Stanley H. (Placitas NM) Vawter Gregory A. (Albuquerque NM), Coherent optical monolithic phased-array antenna steering system.
Calvani Riccardo (Pino Torinese ITX) Vezzoni Emilio (Turin ITX), Device for extraction and re-insertion of an optical carrier in optical communications networks.
Park Yong-Woo (Suwon KRX) Yeo Min-Ki (Suwon KRX) Kim Young-Chul (Seoul KRX) Kim Dong-Yool (Seoul KRX) Lee Hong-Jik (Seoul KRX) Koide Hideki (Tokyo JPX), Document image signal processor having an adaptive threshold.
Liu Karen ; Wang Weyl-kuo ; Yue Chaoyu, Dynamic optical add-drop multiplexers and wavelength-routing networks with improved survivability and minimized spectra.
Chang, Gee-Kung; Way, Winston I., High-throughput, low-latency next generation internet networks using optical label switching and high-speed optical header generation, detection and reinsertion.
Hiscock James Scott ; Wils Joris Johannes Maria ; Van Seters Stephen Luke ; Heiner ; Jr. Edward A. ; Friedman G. Stodel ; Harrison ; Jr. John Joseph, Logical switch set.
Eric A. Swanson ; Richard Barry ; Murat Azizoglu, Method and apparatus for improving transmission performance over wavelength division multiplexed optical communication links using forward error correction coding.
Alagar,Sridhar; Pheiffer,Brian; Sharma,Rohit; St. Laurent,Stephane; Jessup,Holden D.; Iraschko,Rainer, Method and system for bi-directional path switched network.
Chraplyvy Andrew R. (Matawan NJ) Forghieri Fabrizio (Princeton NJ) Tkach Robert W. (Little Silver NJ), Multi-channel optical fiber communication system.
Egnell, Lars; Johansson, Bengt; Batchellor, Robert; Wood, Nigel; Oberg, Magnus, Optical WDM network having an efficient use of wavelengths and a node therefor.
Chang Gee-Kung ; Ellinas Georgios ; Graveman Richard ; Monma Clyde, Optical layer survivability and security system using optical label switching and high-speed optical header generation and detection.
Doerr Christopher R. (Atlantic Highlands NJ) Glance Bernard (Colts Neck NJ) Kaminow Ivan P. (Holmdel NJ), Optically restorable WDM ring network using simple add/drop circuitry.
Henry Charles Howard ; Lenz Gadi ; Li Yuan P. ; Madsen Christi Kay ; Presby Herman Melvin ; Scotti Ronald Edward, Reconfigurable add-drop multiplexer for optical communications systems.
Shiragaki, Tatsuya; Henmi, Naoya; Nishio, Makoto; Takeshita, Hitoshi; Shimomura, Hirofumi, Ring network for sharing protection resource by working communication paths.
Sargis Paul D. (Modesto CA) Haigh Ronald E. (Tracy CA) McCammon Kent G. (Livermore CA), Subcarrier multiplexing with dispersion reduction and direct detection.
Vanoli Stefano,ITX ; Tamburello Mario,ITX, Telecommunication system and method for wavelength-division multiplexing transmissions with a controlled separation of t.
Alexander Stephen B. ; Chaddick Steve W. ; Litz Roy ; Smith Cecil D., WDM Optical communication systems with remodulators and remodulating channel selectors.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.