Shared optical performance monitoring
First Claim
1. An optical monitoring apparatus comprising:
- at least two optical monitoring input ports each to receive a respective set of incoming wavelengths;
an optical combiner to combine light received at the monitoring input ports into a combined monitoring signal;
a wavelength sensitive power monitoring device to determine a power measurement per wavelength of the combined monitoring signal; and
a power measurement processor adapted to process the power measurements to produce per-monitoring input port information;
wherein the power measurement processor is adapted to determine a total power incoming from a particular monitoring input port according to a wavelength map of incoming wavelengths to this particular port with an assumption that the sets of incoming wavelengths are non-overlapping.
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Accused Products
Abstract
An apparatus for shared optical performance monitoring (OPM) is provided. A wavelength sensitive device receives light at an input port and routes it wavelength selectively to a set of output ports. To perform optical performance monitoring on the output ports, a monitoring component of each output signal is extracted, and these monitoring components are then combined. A single OPM function is then performed on the combined signal. However, with knowledge of the wavelengths that were included in each output signal, a virtual OPM function can be realized for each output port. The per port functionality can include total power per port, power per wavelength per port, variable optical attentuation, dynamic gain equalization, the latter two examples requiring feedback.
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Citations
39 Claims
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1. An optical monitoring apparatus comprising:
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at least two optical monitoring input ports each to receive a respective set of incoming wavelengths; an optical combiner to combine light received at the monitoring input ports into a combined monitoring signal; a wavelength sensitive power monitoring device to determine a power measurement per wavelength of the combined monitoring signal; and a power measurement processor adapted to process the power measurements to produce per-monitoring input port information; wherein the power measurement processor is adapted to determine a total power incoming from a particular monitoring input port according to a wavelength map of incoming wavelengths to this particular port with an assumption that the sets of incoming wavelengths are non-overlapping. - View Dependent Claims (2, 3, 4, 5)
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6. An optical monitoring apparatus comprising:
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at least two optical monitoring input ports each to receive a respective set of incoming wavelengths; an optical combiner to combine light received at the monitoring input ports into a combined monitoring signal; a wavelength sensitive power monitoring device to determine a power measurement per wavelength of the combined monitoring signal; and a power measurement processor adapted to process the power measurements to produce per-monitoring input port information; wherein the power measurement processor is adapted to determine a power per wavelength for each wavelength corresponding to a particular monitoring input port according to a wavelength map of incoming wavelengths to this particular port with an assumption that the sets of incoming wavelengths are non-overlapping. - View Dependent Claims (7)
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8. An optical monitoring apparatus comprising:
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at least two optical monitoring input ports each to receive a respective set of incoming wavelengths; an optical combiner to combine light received at the monitoring input ports into a combined monitoring signal; a wavelength sensitive power monitoring device to determine a power measurement per wavelength of the combined monitoring signal; and a power measurement processor adapted to process the power measurements to produce per-monitoring input port information; wherein the optical combiner applies a set of combiner'"'"'s ratios to signals received at the monitoring input ports, and the power measurement processor takes into account the combiner'"'"'s ratios in producing the per-monitoring input port information.
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9. An apparatus comprising:
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at least one input port, wherein a respective optical signal containing at least one wavelength is receivable at each input port; a first wavelength sensitive device to separate the wavelengths received at the at least one input port into at least two output signals containing non-overlapping subsets of wavelengths; an optical combiner to combine at least two of the output signals or monitoring components of at least two of the output signals to produce a monitoring signal; a wavelength sensitive power monitoring device optically connected to receive the monitoring signal; a self-test input for inputting a test signal to the wavelength sensitive device; and a power measurement processor adapted to process the power measurements to produce per output signal information, and to generate feedback control signals as a function of the power measurements compared to known self-test input. - View Dependent Claims (10, 11, 12, 13, 14, 15, 16, 17)
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18. An apparatus comprising:
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at least one input port, wherein a respective optical signal containing at least one wavelength is receivable at each input port; a first wavelength sensitive device to separate the wavelengths received at the at least one input port into at least two output signals containing non-overlapping subsets of wavelengths; an optical combiner to combine at least two of the output signals or monitoring components of at least two of the output signals to produce a monitoring signal; and a wavelength sensitive power monitoring device optically connected to receive the monitoring signal; a self-test input for inputting a test signal to the wavelength sensitive device; and a power measurement processor adapted to process the power measurements to produce per output signal information, and to perform calibration of the wavelength sensitive device as a function of the power measurements compared to known self-test input.
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19. An apparatus comprising:
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at least one input port, wherein a respective optical signal containing at least one wavelength is receivable at each input port; a first wavelength sensitive device to separate the wavelengths received at the at least one input port into at least two output signals containing non-overlapping subsets of wavelengths; an optical combiner to combine at least two of the output signals or monitoring components of at least two of the output signals to produce a monitoring signal; a wavelength sensitive power monitoring device optically connected to receive the monitoring signal; and a power measurement processor adapted to process power measurements to produce per output signal information. - View Dependent Claims (20, 21, 22, 23, 24, 25)
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26. An apparatus comprising:
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at least one input port, wherein a respective optical signal containing at least one wavelength is receivable at each input port; a first wavelength sensitive device to separate the wavelengths received at the at least one input port into at least two output signals containing non-overlapping subsets of wavelengths; an optical combiner to combine at least two of the output signals or monitoring components of at least two of the output signals to produce a monitoring signal; and a wavelength sensitive power monitoring device optically connected to receive the monitoring signal; wherein the wavelength sensitive device is adapted to attenuate each wavelength by a respective amount, the apparatus further comprising;
a control element adapted to feed back a control signal to the wavelength sensitive device to impose a predetermined attenuation profile with respect to wavelength for each output signal.
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27. An apparatus comprising:
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at least one input port, wherein a respective optical signal containing at least one wavelength is receivable at each input port; a first wavelength sensitive device to separate the wavelengths received at the at least one input port into at least two output signals containing non-overlapping subsets of wavelengths; an optical combiner to combine at least two of the output signals or monitoring components of at least two of the output signals to produce a monitoring signal; and a wavelength sensitive power monitoring device optically connected to receive the monitoring signal; wherein the wavelength sensitive device is adapted to attenuate each output signal by a respective amount, the apparatus further comprising;
a control element adapted to feedback a control signal to control the attenuation applied to each output signal.
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28. An apparatus comprising:
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at least one input port, wherein a respective optical signal containing at least one wavelength is receivable at each input port; a first wavelength sensitive device to separate the wavelengths received at the at least one input port into at least two output signals containing non-overlapping subsets of wavelengths; an optical combiner to combine at least two of the output signals or monitoring components of at least two of the output signals to produce a monitoring signal; and a wavelength sensitive power monitoring device optically connected to receive the monitoring signal; wherein said wavelength sensitive device comprises; diffractive elements working at a main diffraction order to couple an input multi-wavelength signal to a plurality of output ports 1 to K; a second set of output ports 1′
to K′
for outputting signals of another diffraction order, wherein signals output by the second set of output ports are combined by said optical combiner to produce the monitoring signal;wherein the first set of output ports and the second set of output ports are arranged such that coupling from the input to the second output port i is related by a predetermined and fixed relationship to the coupling from the input to the corresponding first output port i for each given wavelength.
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29. An apparatus comprising:
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at least one input port, wherein a respective optical signal containing at least one wavelength is receivable at each input port; a first wavelength sensitive device to separate the wavelengths received at the at least one input port into at least two output signals containing non-overlapping subsets of wavelengths; an optical combiner to combine at least two of the output signals or monitoring components of at least two of the output signals to produce a monitoring signal; and a wavelength sensitive power monitoring device optically connected to receive the monitoring signal; wherein the optical combiner applies a set of combiner'"'"'s ratios in producing the monitoring signal, and the power measurement processor takes into account the combiner'"'"'s ratios when processing the power measurements to produce per output signal information.
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30. A tap and continue arrangement comprising:
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a plurality of waveguides carrying signals to be monitored; a crossing waveguide that crosses the plurality of waveguides so as to couple a small fraction of each signal to be monitored into the crossing waveguide; a wavelength sensitive power monitoring device connected to receive an output of the crossing waveguide to make per-wavelength power measurements; and a power measurement processor adapted to process the power measurements to produce information for each of said plurality of waveguides; wherein the power measurement processor is adapted to determine a total power incoming from each of the plurality of waveguides according to a wavelength map of incoming wavelengths to this particular waveguide with an assumption that the sets of incoming wavelengths are non-overlapping.
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31. A tap and continue arrangement comprising:
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a plurality of waveguides carrying signals to be monitored; a crossing waveguide that crosses the plurality of waveguides so as to couple a small fraction of each signal to be monitored into the crossing waveguide; a wavelength sensitive power monitoring device connected to receive an output of the crossing waveguide to make per-wavelength power measurements; and a power measurement processor adapted to process the power measurements to produce information for each of said plurality of waveguides; wherein the power measurement processor is adapted to determine a power per wavelength for each wavelength corresponding to a particular waveguide of the plurality of waveguides according to a wavelength map of incoming wavelengths to this waveguide with an assumption that the sets of incoming wavelengths are non-overlapping.
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32. A method of performing optical performance monitoring comprising the following steps:
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(a) receiving a plurality of monitoring components; (b) combining the monitoring components into a combined monitoring signal; (c) determining a power measurement per wavelength of the combined monitoring signal; and (d) processing the power measurements to produce per-monitoring component information; wherein step (d) comprises determining a total power in particular monitoring component according to a wavelength map of incoming wavelengths to this particular monitoring component with an assumption that the sets of incoming wavelengths are non-overlapping. - View Dependent Claims (33, 34, 35, 36)
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37. A method of performing optical performance monitoring comprising the following steps:
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(a) receiving a plurality of monitoring components; (b) combining the monitoring components into a combined monitoring signal; (c) determining a power measurement per wavelength of the combined monitoring signal; and (d) processing the power measurements to produce per-monitoring component information; wherein step (d) comprises determining a power per wavelength for each wavelength corresponding to a particular monitoring component according to a wavelength map of incoming wavelengths to this particular monitoring component with an assumption that the sets of incoming wavelengths are non-overlapping. - View Dependent Claims (38)
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39. A method of performing optical performance monitoring comprising the following steps:
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(a) receiving a plurality of monitoring components; (b) combining the monitoring components into a combined monitoring signal; (c) determining a power measurement per wavelength of the combined monitoring signal; and (d) processing the power measurements to produce per-monitoring component information; wherein step (b) comprises applying a set of combiner'"'"'s ratios to the monitoring components, and the processing takes into account the combiner'"'"'s ratios in producing the per-monitoring component information.
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Specification