WDM channel monitoring system and method

Optical communications – Optical repeater system – Monitoring

Reexamination Certificate

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Details

C398S033000

Reexamination Certificate

active

06748179

ABSTRACT:

FIELD OF THE INVENTION
This invention relates to the field of optical communication systems, and more particularly, this invention relates to an optical communication system using wavelength division multiplexed (WDM) optical communication signals and having back-up receiver capability.
BACKGROUND OF THE INVENTION
Wavelength division multiplexing (WDM) is commonly used in optical communication systems for increasing the bandwidth of a fiber optic telecommunications link, without increasing the speed of associated electronics. In many prior art optical communication techniques, the bandwidth of a single channel (or wavelength fiber optic telecommunication link) has been limited primarily by the high-speed electronics required at the transmitter and receiver. By using wavelength division multiplexing at a telecommunications system receiver, the optical channels that receive the optical communication signals are separated, or demultiplexed, and sent to individual receivers, which vary in their rate of data receipt. One example of a receiver is a 2.488 Gb/S receiver.
The number of individual receivers used in the optical communications system can vary. These communication receivers connect into a back plane of existing telecommunications equipment. For example, a telecommunications rack could include one or more receivers, such as 8 or 16 receivers, each mounted on a board within the telecommunications rack. When optical components fail, it is necessary to determine the channel that is being used by the failed optical component or particular receiver.
In the past, telecommunication links have rerouted signals on the electrical switching level when any optical components failed, thus loading another path onto the network. It would be more advantageous to re-route an optical communication signal on a particular wavelength channel at the receiver terminal, in the case of a receiver failure or other optical component failure, and not consume network bandwidth as in prior art techniques. This would allow receiver maintenance at any time without increasing downtime or network re-routing.
It would also be desirable to monitor a channel and allow continuous sweeping of the optical communications channels. For example, if a channel showed any signs of weakening or failure, it would be advantageous to identify the source of the problem so that corrective measures could be sought. Thus, there is a need for greater channel monitoring capability. Although there are some channel monitoring devices that use single mode fiber, such as one commercially available system manufactured under the trade designation “Spectra SPAN,” it has no capability as a back-up signal receiver.
SUMMARY OF THE INVENTION
The present invention is advantageous and allows the re-routing of optical communication signals at the receiver terminal, in case of receiver failure or other optical component failure. The system also does not consume network bandwidth as in past practices, where signals have been re-routed on the electrical switching level when optical components failed. Thus, in the present invention, another path is not loaded onto the network and bandwidth is not consumed. The present invention also allows receiver maintenance at any time, without down time or network re-routing.
The present invention can also function as a channel monitor, allowing continuous sweeping of optical communication channels for quality and performance. When a channel shows signs of weakening or failure, identification of the source of the problem can be triggered, and corrective measures sought. If any one of the dedicated telecommunications system receivers fail on any given wavelength, the back-up receiver system of the present invention can be tuned to that particular wavelength and take over the link, while repairs are being conducted.
The present invention can also be used as a tracking filter for systems that use a tunable laser for laser transmitters that fail. The receiver can track to a new wavelength location where a tunable transmitter has been positioned to account for a failing, or a failed laser transmitter. The present invention can also be used as a tunable receiver for systems/locations requiring tunability, such as add/drop nodes on a fiber.
In accordance with the present invention, the system monitors the performance of an optical communications channel and includes an optical splitter positioned along an optical communications path for receiving a wavelength division multiplexed (WDM) optical communications signal on the optical communications path. This signal is split into a low power WDM signal onto a back-up path where a tunable filter receives the low power WDM optical signal and sweeps the optical communications channels. A monitoring circuit is operatively connected to the tunable filter and monitors the optical communications channels for performance. The tunable filter is swept and the optical power is stored and subsequently displayed, providing an optical spectrum analysis of the signal. The optical amplifier can receive the low power WDM signal and amplify same after splitting from the optical communications signal.
In another aspect of the present invention, the amplifier includes an injection laser diode and a current source control loop circuit connected to the injection laser diode that establishes a fixed current through the injection laser diode. A voltage switcher circuit is connected to the injection laser diode and current source control loop circuit. The tunable filter can comprise a Fabry Perot filter. The controller can be operatively connected to the tunable filter in a controller feedback path for controlling the selection of desired wavelengths corresponding to the optical communications channels.


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