JP2010081297A - Full optical network operating managing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a full optical network operating managing device which can collect signal optical characteristic information of an optical path in a full optical network. <P>SOLUTION: The full optical network operating managing device includes: selecting an optical node and an optical path wavelength on an optical path route to be monitored from optical path route information; setting a signal optical bit rate included in the optical node and a wavelength in an optical signal quality monitor independent of a signal optical modulation system; instructing a measurement of the signal optical characteristic information of the wavelength to the optical signal quality monitor; receiving the signal optical characteristic information of the measured wavelength; and holding it in a database. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an all-optical network operation management apparatus that collects signal light characteristic information of optical paths in an all-optical network. Note that the all-optical network indicates an optical network that performs path switching without changing the photoelectric conversion process at each node.

  In a conventional optical network, optical path quality monitoring is performed using a method in which signal light is subjected to photoelectric conversion processing at each node and quality information (bit error rate) is read. Further, Patent Document 1 discloses an apparatus that can economically implement quality management functions and fault isolation functions for each wavelength in an all-optical network.

JP 2008-166935 A

  However, in an all-optical network, the path is switched as it is without passing through the photoelectric conversion process at each node, so it is difficult to apply the conventional optical path quality monitoring method based on the photoelectric conversion process.

  Therefore, the present invention provides an all-optical network capable of collecting signal light characteristic information of an optical path in an all-optical network by using an optical signal quality monitoring device that does not depend on the signal light bit rate and the signal light modulation method. An object is to provide an operation management apparatus.

  In order to achieve the above object, an all-optical network operation management apparatus according to the present invention, means for holding optical path route information of an all-optical network, and optical nodes on the optical path route to be monitored and monitored from the optical path route information. Means for selecting an optical path wavelength; means for setting the wavelength in an optical signal quality monitoring device independent of the optical signal bit rate and optical signal modulation system provided in the selected optical node; and the optical signal quality monitoring Means for instructing the apparatus to measure the signal light characteristic information of the wavelength; means for receiving the signal light characteristic information of the wavelength measured by the optical signal quality monitoring apparatus; and means for storing the received signal light characteristic information And.

  The optical path to be monitored is preferably a newly generated optical path, an optical path in which a failure has occurred, or a path requested for quality control.

  Means for holding topology information of the all-optical network; means for associating the signal light characteristic information with the optical path path information; and an optical node in which the signal light characteristic information has deteriorated from the topology information and the association; It is also preferable to further comprise means for obtaining an optical path route between optical nodes that have not deteriorated, and to determine that a failure has occurred in the optical path route.

  Further, it is preferable that the apparatus further includes means for executing switching of the optical path route in which the failure has occurred when it is determined that a failure has occurred in the optical path route.

  According to the present invention, conventional optical / electrical conversion is also achieved in an all-optical network by collecting signal light characteristic information from the all-optical network using an optical signal quality monitoring device that does not depend on the signal light bit rate and the signal light modulation method. Quality monitoring equivalent to signal light quality monitoring based on processing can be performed. Further, by mapping the optical path information and the signal light characteristic information, it is possible to provide a mechanism for monitoring the optical path quality, detecting the link fault, and specifying the fault section.

  The best mode for carrying out the present invention will be described in detail below with reference to the drawings.

  FIG. 1 shows an overview of an all-optical network in the present embodiment. The all-optical network includes an all-optical network operation management device 1, an optical signal quality monitoring device 2, an optical node 3, and an optical transmission / reception device 4.

  The all-optical network operation management device 1 is a device for managing the all-optical network, and holds all-optical network configuration information. This configuration information includes all-optical network topology information and optical path route information including port information through which an optical signal passes.

  The optical signal quality monitoring device 2 is a device that collects signal light characteristic information without depending on the signal light bit rate and format (signal light modulation method). The signal light characteristic of the optical path provided in the optical node 3 and transmitted to the optical node 3 is monitored, and the signal light characteristic information is measured. The optical signal quality monitoring device 2 has a wavelength selection switch inside, and the wavelength selection switch allows only the monitoring wavelength to pass from the WDM signals from a plurality of directions by setting the monitoring wavelength from the outside. . Therefore, the optical signal quality monitoring device 2 can collect only the signal light characteristic information of the wavelength that needs to be monitored.

In the present embodiment, the optical signal quality monitoring device 2 measures the signal light quality (Q value) as the signal light characteristic information. The signal light quality is measured using the eye waveform of the signal light. Specifically, in the case of phase-modulated signal light, the optical signal quality monitoring device 2 splits the optical signal to be monitored into two, and gives one optical signal a phase shift that periodically changes in the range of 0 to π. The quality of the optical signal is measured after demodulating the signal light by combining the two optical signals. At this time, the time when the eye opening of the eye waveform is the maximum is used as a criterion for optimization. In the demodulation of the phase-modulated signal light, a delay of one symbol interval is given to the optical path between the two branches, but here the purpose is not to completely demodulate but to monitor the waveform quality and to quantify the quality. Therefore, the delay amount can be an integral multiple of one symbol interval. That is, in the case of optical signals having symbol intervals that are integral multiples of each other, the optical signal can be monitored by setting the delay amount to the least common multiple of the symbol intervals of these optical signals. In the case of amplitude shift keyed signal light, the eye waveform is measured by bypassing the signal light demodulating portion with an optical switch. The quality of the optical signal is obtained by obtaining a quality index Q value obtained from the eye waveform of the optical signal (reference document: ITU-T recommendation O.201, “Q-factor test equipment to estimate the transmission performance of optical channels”). The Q value is measured by converting the combined optical signal into an electrical signal, observing the waveform, and subsequently sampling the electrical signal, and sampling the maximum value I ₁ (1 level) and the minimum value I ₀ (0). Level), that is, the eye opening (I ₁ -I ₀ ), the period to be used for measurement is determined, and the distribution of the maximum value (σ ₁ ) and the distribution of the minimum value (σ ₀ ) in the determined period Q value from Q = (I ₁ −I ₀ ) / (σ ₁ + σ ₀ )
Ask for.

  The optical node 3 is a switch for switching the path of the optical path, and switches the path without performing electrical processing. The optical transmitter / receiver 4 is a device for transmitting and receiving an optical signal.

  When the optical path indicated by the arrow in FIG. 1 is generated between the optical transmission / reception apparatuses 4, the all-optical network operation management apparatus 1 is generated in the optical signal quality monitoring apparatus 2 through the control line of the optical network control / management network. Require optical path wavelength quality measurement. This request is made to the optical signal quality monitoring device 2 provided in the optical node 3 in the path of the optical path. This quality measurement request is made not only when an optical path is generated, but also when a failure occurs and when a user requests optical path quality management.

  The exchange of information between the all-optical network operation management device 1 and the optical signal quality monitoring device 2 in the quality measurement request and the operation of each device will be described in detail below.

  FIG. 2 shows the exchange of information between the all-optical network operation management apparatus and the optical signal quality monitoring apparatus according to the present invention.

  In the exchange of information, the all-optical network operation management device 1 instructs the optical signal quality monitoring device 2 to “monitoring optical path information” for specifying the optical path to be monitored, and to measure the optical path quality to be monitored. It consists of “measurement information” and “quality information” for returning the signal light quality measurement result from the optical signal quality monitoring device 2 to the all-optical network operation management device 1.

  The optical signal quality monitoring device 2 that has received the “monitoring optical path information” having the wavelength and port information of the optical path to be monitored becomes the measurement target in order to measure the signal light quality of the optical path to be monitored. Select the signal light. Next, the optical signal quality monitoring apparatus 2 that has received the “measurement information” measures the quality of the signal light under measurement in accordance with the parameters included in the “measurement information”. After the measurement, the quality information of the signal light under measurement is put on “quality information” and returned to the all-optical network operation management apparatus 1.

  FIG. 3 shows a flow when measuring the optical path quality of the all-optical network operation management apparatus.

  S1: The all-optical network operation management apparatus 1 starts signal light quality measurement when an optical path is generated, when a failure occurs in the optical path, or when a user requests it.

  S2: The all-optical network operation management apparatus 1 transmits port and wavelength information for selecting a measurement target signal to the optical signal quality monitoring apparatus 2 based on the optical path route information that the all-optical network operation management apparatus 1 has. .

  S3: The optical signal quality monitoring device 2 selects a wavelength to be measured using a wavelength selection switch. It is also possible to use an optical filter, a wavelength blocker, or the like for wavelength selection (references: for example, Jonathan Homa et al., “ROADM Architecture and Their Enabling WSS technology,” IEEE Communication magazine, June 2008, pp. 150-154).

  S4: The all-optical network operation management device 1 selects synchronous measurement or asynchronous measurement. If the signal light baud rate (Baud rate) to be measured is known in advance, synchronous measurement is selected. If the signal baud rate is unknown, select asynchronous measurement. Based on this selection, parameters for signal light quality measurement are set. In synchronous measurement, the time axis of the signal to be measured is set. In asynchronous measurement, the time axis is not set.

  S5: In the case of synchronous measurement, the all-optical network operation management device 1 transmits the baud rate information (measurement information) of the measurement target signal to the optical signal quality monitoring device 2. In the case of asynchronous measurement, transmission of the baud rate is not necessary.

  S6: The optical signal quality monitoring device 2 sets the baud rate according to the measurement information in S5. Thereby, the time axis of the signal to be measured can be determined.

  S7: The all-optical network operation management device 1 instructs the optical signal quality monitoring device 2 to optimize.

  S8: The optical signal quality monitoring device 2 optimizes the state of the optical signal quality monitoring device 2. The optimization means setting the optical signal quality monitoring device 2 in a state where the maximum quality can be measured. Further, when the optical signal is in a phase shift keying (PSK) modulation method, optimization is required, but an amplitude shift keying (ASK) modulation method, that is, on-off keying (OOK: On Off). When Keying), no optimization is necessary.

  S9: When the optimization is completed, the optical signal quality monitoring device 2 transmits an optimization end message to the all-optical network operation management device 1.

  S10: The all-optical network operation management device 1 confirms that the optimization of the optical signal quality monitoring device 2 has been completed.

  S11: The all-optical network operation management device 1 transmits a signal light quality measurement start message to the optical signal quality monitoring device 2 in order to start measuring the signal light quality.

  S12: The optical signal quality monitoring device 2 performs measurement of the signal light quality (Q value).

  S13: The optical signal quality monitoring device 2 acquires the signal light quality (Q value) obtained by the measurement and sends it to the all-optical network operation management device 1.

  S14: The all-optical network operation management apparatus 1 stores the signal light quality (Q value) transmitted from the optical signal quality monitoring apparatus 2 in the database of the all-optical network operation management apparatus 1.

  S15: The all-optical network operation management device 1 ends the measurement of one optical signal quality monitoring device 2 after obtaining the signal light quality (Q value).

  S16: The optical signal quality monitoring device 2 cancels the selection of the wavelength to be measured.

  S17: The all-optical network operation management device 1 checks whether it is the final measurement point. If it is not the final measurement point after the measurement is completed, the process proceeds to the next port measurement (S2) according to the optical path route information. In the case of the final measurement point, the measurement ends.

  By using the optical signal quality monitoring device 2 independent of the optical signal bit rate and format arranged at each point such as an optical node or a repeater of the all-optical network, the signal optical quality is obtained from the device by the above procedure. collect.

  FIG. 4 shows an example of optical path quality monitoring, link failure detection, and failure section identification using an all-optical network operation management device. FIG. 4 a shows that the all-optical network operation management apparatus 1 collects signal light quality information from the optical node 1 to the optical node 4. FIG. 4b shows an example in which the obtained quality information and the optical path route are mapped.

  The all-optical network operation management apparatus 1 can grasp the signal light quality along the optical path route by measuring the signal light quality according to the optical path route and mapping the obtained quality information and the optical path route. . As a result, it becomes possible to identify signal light quality degradation or failure sections. In addition, the optical path route can be switched after the failure section is specified.

  For example, when a failure occurs in the optical transmission path between the optical node 2 and the optical node 3, the signal light quality deteriorates (Q value decreases) in the optical node 3 and the optical node 4 downstream from the failure point. Since the all-optical network operation management apparatus 1 holds topology information as all-optical network configuration information, the upstream of the optical node 3 and the optical node 4 is the optical node 2, and the upstream of the optical node 2 is the optical node 1. I recognize that. Further, the quality information from the optical signal quality monitoring device 2 and the optical path route are mapped as shown in FIG. 4b. Therefore, it can be recognized that a failure has occurred in the optical path path between the optical node 2 and the optical node 3.

  Moreover, all the embodiments described above are illustrative of the present invention and are not intended to limit the present invention, and the present invention can be implemented in other various modifications and changes. Therefore, the scope of the present invention is defined only by the claims and their equivalents.

1 shows an overview of an all-optical network in the present embodiment. Fig. 3 shows an exchange of information between an all-optical network operation management device and an optical signal quality monitoring device according to the present invention. The flow at the time of optical path quality measurement of the all-optical network operation management apparatus is shown. An example of optical path quality monitoring, link failure detection, and failure section identification using an all-optical network operation management apparatus will be described.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 All-optical network operation management apparatus 2 Optical signal quality monitoring apparatus 3 Optical node 4 Optical transmission / reception apparatus

Claims (4)

Means for holding optical path route information of the all-optical network;
Means for selecting an optical node on the optical path route to be monitored and an optical path wavelength to be monitored from the optical path route information;
Means for setting the wavelength in the optical signal quality monitoring device independent of the optical signal bit rate and optical signal modulation system provided in the selected optical node;
Means for instructing the optical signal quality monitoring device to measure the signal light characteristic information of the wavelength;
Means for receiving the signal light characteristic information of the wavelength measured by the optical signal quality monitoring device;
Means for storing the received signal light characteristic information;
An all-optical network operation management device comprising:   2. The all-optical network operation management apparatus according to claim 1, wherein the optical path to be monitored is a newly generated optical path, an optical path in which a failure has occurred, or a path for which quality management is requested. Means for maintaining topology information of the all-optical network;
Means for associating the signal light characteristic information with the optical path route information;
Means for obtaining an optical path route between an optical node in which the signal light characteristic information has deteriorated and an optical node in which the signal light characteristic information has not deteriorated, from the topology information and the association;
The all-optical network operation management apparatus according to claim 1, further comprising: determining that a failure has occurred in the optical path route.   4. The all-optical network operation management apparatus according to claim 3, further comprising means for executing switching of an optical path route in which a failure has occurred when it is determined that a failure has occurred in the optical path route.

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