TH41802A3 - Methods and systems for detecting signal loss in wavelength division multiplexed systems. - Google Patents

Abstract

DC60 (21/01/54) Methods and systems for performing fiber break detection. There is no ambiguity in the optical network, regardless of the number of EDFAs that are positioned during fiber absences. With the checkpoint In accordance with the invention of the inventor Has compared the power of The wavelength of the sign signal and the power of the neighboring spectral region when the comparison indicates that the power ratio is approximately one. Will establish an indicator which indicates there is Lack of fiber When the comparison indicates that the power ratio is greater than one, no Set up indicator The monitoring point consists of a circuit to detect the ratio between The wavelength of the marking signal with the neighboring spectral band. And for indicating When there is a lack of fiber Methods and systems for conducting a fiber defect detection There is no ambiguity in the optical network, regardless of the number of EDFAs that are positioned during fiber absences. With the checkpoint In accordance with the invention of the inventor Has compared the power of The wavelength of the sign signal and the power of the neighboring spectral region when comparison indicates that the power ratio is approximately equal to one. Will establish an indicator which indicates there is Lack of fiber When the comparison indicates that the power ratio is greater than one, no Set up indicator The monitoring point consists of a circuit to detect the ratio between The wavelength of the marking signal with the neighboring spectral band. And for indicating When there is a lack of fiber

Claims (1)

Disclaimer (all) that will not appear on the advertisement page: 1. In the system of wavelength division multiplexing. Which contains at least two nodes Interconnected by fiber paths, there is at least one optical circuit obtained Get connected too Method for detecting fiber deficiency at one point of the node. The method is combined with a process of Generation of the wavelength of the marker signal and the determination of the power ratio between the wavelength of the said occurring marking signal and the neighboring spectral band at one such node. 2. Method according to the claim in Here, the wavelength of the marker signal that forms Such a generator is the compensation channel of the amplifier. 4. A system for detecting fiber faults on one fiber with an amplifier. Of at least one circuit Between the checkpoint and the fiber deficiency, the system includes Circuit for generating a channel for compensation; And a circuit for detecting the power ratio between channels for the generating compensation band, the spectral band with the same gain Approximately with the channel for compensation The circuit of the channel for such compensation And the detection circuit is connected to the fibers in such a way that the absence at the location Somewhere The line of the fibers was detected. 5. System which complies with claim No. 4. Here, the circuit of such detection also It consists of a circuit to indicate the absence of fibers if the capture ratio is equal to Approximately one And for indicating that the fibers are intact If the detectable ratio is greater than one. 6. Wavelength division multiplexing system. Which includes At least two nod elements that make it interconnected by a working fiber and a spare fiber. A number of amplification circuits in these fibers and a method for determining the deficiency of fibers in one such fiber includes a method for comparing power ratios between The wavelength of the marking signal on one such fiber With nearby spectral bands 7. Multiplexing system Wavelength division This is in line with claim No. 6. Here, the amplifier is an erbium-contaminated amplifier. 8. A system of wavelength division multiplexing. This is consistent with claim No. 7. Here, the elements of the said node It is arranged in a ring configuration. 9. Wavelength division multiplexing system. In accordance with claim 8, it also includes a laser that connects to the aforementioned optical fibers. 1 0. System of wavelength division multiplexing This is consistent with claim No. 7. Here at least one such extension circuit consists of a path for interpolation. Channel for offset into the fiber The aforementioned amplification circuit is located 1 1. System of wavelength division multiplexing. Which includes Two nodular elements that make it interconnected by active fibers and spare fibers; An amplifier containing a certain amount of erbium in the fibers. A path for determining the determination of the deficiency of a fiber in one such fiber. The path includes a method for comparing the power ratio between The wavelength of the marking signal on one such fiber Block nearby spectral bands; And herein the wavelengths of the aforementioned sign signal are provided by an erbium-doped amplifier. Which includes At least two nod elements making them interconnected by functional fibers and alternate fibers, such node elements are arranged in a configuration. Point to point characteristics Buzzing circuits in the fibers A path for determining the deficiency of a fiber connected to one such fiber. The path includes a method for comparing the power ratios between The wavelength of the marking signal on one such fiber and the neighboring spectral band; And the pathway that responds to the path for determining for the switching from the fibers used Line-to-work in reserve 1 3. Methods for detecting fiber defects in systems of conventional multiplexing. Split wavelength There is at least one amplification circuit between the two node elements. The approach consists of comparing the power ratios at the upper monitoring point. Fibers between power in the first spectral band and power in the adjacent spectral band 1 4. Method, which is consistent with claim 13, hereinafter, such detection at the rate Approximately one power fraction indicates a fiber deficiency in the fiber. 1 5. Method, consistent with claim 14, here the spectral region where the One such one consists of a transponder of the sign 1 6. The method, in accordance with claim 14, also includes a procedure for the Inserting the signal channel into the said fiber 1 7. Method in accordance with claim 16 here, the signal channel The marking has been interpolated with a laser 1 8. Method, in accordance with Clause 16. Here at least one such amplifier circuit is a compensated erbium-doped fiber amplifier. And the channel of The mark signal has been inserted into the fibers as a channel for Compensation of one such amplifier circuit 1 9. Methods for detecting fiber faults in systems of multiplexing. Split wavelength Where at least one amplification circuit is between the two node elements. The approach is combined by comparing the power ratios at the upper monitoring point. The spectral fibers in the first spectral band and the power in the adjacent spectral band, hereby a detection with approximately one power ratio indicates a lack of Fibers in such fibers Here, the spectral region, the region one, comprises the channels of Sign signal, and herein the amplifier is an erbium-doped fiber amplifier, the channel of Signal mark Includes a channel for compensation of the said amplifier. And the second spectral region contains the signal The use of such fibers 2 0. Methods for detecting fiber deficiency in a system of multiplexing. Split wavelength Which has at least one erbium-doped amplifier between Composition of two nodes The above method consists of comparing ratios. Of power at the monitoring point on the fiber between power in the first spectral band and power in the linear The adjacent spectra, and where and where the first spectral structure is composed of excitation light emission. Which occurs spontaneously through the expansion of such amplifiers And the second spectral region Including the active signal of the said fiber.