JP2005065193A - Node monitoring/control device of optical network - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To set up control node models that can be used in common not depending on a hardware realizing method and to attain that optical network devices can be developed with high efficiency. <P>SOLUTION: The optical network node monitoring/control device is equipped with a means of sorting configurations of optical node devices into functional blocks corresponding to their functions and the other means of allocating the previously set control node models as control softwares to the sorted functional blocks. As to one or more optical node devices, a lookup table where the functional blocks sorted by the sorting means and the corresponding control node models are recorded is provided, and the allocating means is equipped with a means of allocating the control node model to each of the functional blocks resting on the lookup table. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to ITU-T Recommendation G.264. This is used in an optical transmission system that conforms to 872. In particular, the present invention relates to an optical node device control technique.

  In a conventional optical network, a control node model, which is software for controlling the optical node device, is determined for each architecture of the optical node device and used for controlling the optical node device. For example, there are a plurality of methods for realizing an optical node device of an optical network as shown in FIGS. The control node model for each case is shown below and shows that it is greatly different. If they are different, the control node model cannot be shared, so it will be almost remade.

FIG. 5 shows an example in which an optical node device is configured by combining a cross-connect switch that cross-connects ODUs (Optical Date Unit: see Non-Patent Document 1, for example) and a point-to-point system that handles long-distance optical transmission. . In this example, an OTU (Optical
Transport Unit: For example, see Non-Patent Document 1) Connected by signal. In the point-point system, one terminal station is composed of a pair of a transmitter and a receiver, and one system is composed of a pair of terminal stations facing each other.

  In the point-point system, the IF unit of the transmission unit performs OTU termination processing on the OTU signal output from the ODU cross-connect, generates an OTU signal again, performs wavelength multiplexing processing in the MUX unit, and then performs the Post-OA unit. After the optical amplification, the wavelength multiplexed signal is transmitted to the adjacent node through the optical fiber transmission line. The transmitted wavelength multiplexed signal is optically amplified by Pre-OA, wavelength-separated by the DEMUX unit, OTU-terminated by the IF unit, regenerated as an OTU signal, and sent to the ODU cross-connect device.

  Processing in the ODU cross-connect device will be described. The ODU cross-connect device is a cross-connect device having a function of performing signal route editing in units of ODUs. In this conventional example, it is assumed that the ODU cross-connect device is equipped with an OTU interface and at least one type of user interface. Although there is no specific user signal, a signal that can be mapped to an ODU signal by the IF unit is accepted as a user signal. The input user signal is converted into an ODU signal by the IF unit and input to the switch unit.

  On the other hand, the OTU signal input from the point-point system is converted into an ODU signal by the IF unit and input to the switch unit. The ODU signal input to the switch unit is sent to a predetermined output of the switch, and the output signal that is transmitted to other nodes is converted into an OTU signal by the IF unit, and is point-to-point. Sent to the system. On the other hand, what is sent to the user interface is converted into a desired signal format by the IF and output.

FIG. 6 describes the node configuration described with reference to FIG. 5 using a node model for monitoring control. In FIG. 6, OTS is an Optical Transmission Section (see, for example, Non-Patent Document 3), and OMS is an Optical Multiplex.
Represents Section. ODU-CC represents an ODU cross connection. When this model is used, the user signal is input to the ODU-CC from the ODU termination unit and cross-connected there. When a cross-connected signal is transmitted to another node, it is once converted into an OTU signal at the OTU end point of the ODU cross-connect and sent to the point-point system. In the point-point system, OTU termination is once performed at the OTU termination point inside the station, an OTU signal is generated again at the OTU termination point outside the station, wavelength-multiplexed at the OMS termination point, and transmitted to the other station through the OTS termination point. Is done. When a cross-connected signal is sent to the user side, ODU termination processing is performed at the ODU termination point, and the signal is reconverted into a predetermined user signal format and transmitted.

  FIG. 7 shows an example of a node in which the long-distance transmission and the cross-connect function in the second configuration example are integrated. In this example, it is assumed that the IF section has a function of terminating an OTU and outputting an OTU signal. Therefore, the signal to be cross-connected is an OTU signal.

  A signal flow will be described. The user signal is converted into an OTU signal by the IF unit and sent to the switch unit. On the other hand, wavelength multiplexed signals transmitted from other nodes facing each other are optically amplified by Pre-OA and wavelength-separated by the DEMUX unit. The individual signals subjected to wavelength separation are OTU-terminated at the IF unit and are generated again as OTU signals. Thus, the user signal and the signal from the opposite node are input to the switch unit as an OTU signal. The switch unit is cross-connected to a desired output. What is converted into a user signal is OTU terminated in the IF unit, converted into a user signal format, and passed to the user side.

  What is transmitted to the other opposite node is OTU terminated in the IF unit, then generated again as an OTU signal, wavelength-multiplexed in the MUX unit, optically amplified in the Post-OA unit, and then optical fiber transmission line To the adjacent node.

  FIG. 8 shows an example of the node configuration shown in FIG. 7 using a management model. The user signal is converted into an ODU signal at the ODU termination point, and further converted into an OTU signal at the OTU termination point. Signals transmitted from other nodes are subjected to OTS termination processing and then separated into individual OTU signals at the OMS termination point. Each OTU signal is OTU terminated at the OTU termination point on the inter-office side, and again generated as an OTU signal at the OTU termination point inside the station. Thus, the user signal and the signal from another node are converted into an OTU signal, cross-connected by an OTU cross-connection (OTU-CC), and sent to a desired output. What is sent to the user side is subjected to OTU termination processing at the OTU termination point, and is further returned to the user signal via the ODU termination. What is sent to other nodes is terminated at the OTU termination point inside the station, then converted again to an OTU signal at the OTU termination point on the interoffice side, multiplexed at the OMS termination point, and at the OTS termination point This process is sent to other nodes.

  FIG. 9 shows an example in which the output interface on the transmission side in Configuration Example 2 is omitted as the third node configuration example. Such a configuration can be realized by a Delivery & Couples switch or the like (see, for example, Non-Patent Document 4). The user signal is converted into an OTU format by IF and sent to the switch. On the other hand, wavelength multiplexed signals from other nodes are optically amplified by Pre-OA, wavelength-separated into individual optical signals by DEMUX, and input to the switch unit. The switch unit cross-connects to the desired destination of the OTU signal and outputs it. When outputting to the user side, an interface on the user side is selected, converted into a user signal format by the interface unit, and output. When transmitting to another node, wavelength multiplexing processing is performed in the MUX unit, optical amplification is performed by Post-OA, and the result is transmitted to the optical fiber transmission line.

  FIG. 10 shows a node management model in the configuration example 3. The user signal is converted into an ODU signal at the ODU termination point, further converted into an OTU signal at the OTU termination point, and input to the OTU-CC. On the other hand, signals from other nodes are processed at the OTS termination point, separated into wavelength-unit OTU signals at the OMS termination point, and once processed at the OTU termination point, then input to the OTU-CC. . These input OTU signals are cross-connected by OTU-CC and output to a desired route.

  The signal to the user is subjected to OTU termination processing at the OTU termination point, then ODU terminated at the ODU termination point, converted into a user signal format, and sent to the user side. Signals transmitted to other nodes are subjected to wavelength multiplexing and other processes from OTU-CC to OMS, and transmitted to other nodes via the OTS termination point. It should be noted in this node model that the model is described with a bidirectional link, but the actual configuration example is described with a unidirectional link, so there is no interface on the output side. In the above, it is described as if there is an output OTU termination point.

When the signal directions are expanded, it can be seen that the presence or absence of the OTU termination function differs between a signal received from another node and a signal transmitted to another node. In actual node control, control can be realized by regarding the physical output point of the switch as a virtual OTU termination point (see, for example, Non-Patent Document 2).
ITU-T Recommendation G. 709 NTT R & D Vol. 52, no. 3,175 (2003) "Advanced photonic network technology for next-generation network construction (Katsuhiro Shimano, Tetsuo Takahashi, Masafumi Koga, Yoshihiro Takigawa)" ITU-T Recommendation G. 872 F.Kano, T.Kawai, Y.Takigawa, K.Sato, ”Development of photonicrouter (256x256 OLSPs) to realize next generation networkwith MPLambdaS control ', NFOEC2001, proceedingsvol.1, pp.458-464,2001, Baltimore ( USA)

  The actual hardware configuration of the optical node device and the control node model for managing it have been described above for the three examples. In developing the control node model, the information model is not unified, in addition to hardware differences. For example, while the configuration example 1 is an ODU cross-connect, the configuration examples 2 and 3 use an OTU cross-connect. In addition, since the configuration examples 2 and 3 have different OTU termination point configurations, it is necessary to develop software individually. In other words, it has been difficult to improve the efficiency of optical network system development by diverting existing software or using shared software.

In recent years, GMPLS (Generalized
Multi-Protocol Label Switching) technology is attracting attention, but even if the control program is unified by GMPLS, the development of individual node systems is carried out from the basic part every time, and the effect of using a common control protocol There were few. FIG. 11 simply shows the relationship between the control node model in the conventional configuration and the hardware of the optical network system. It can be seen that a common control protocol is used by using a control node model and hardware specific to device A, specific to device B, specific to device B, and specific to device C.

  As described above, the control node model of the conventional optical transmission system has a large part depending on hardware, and there are few parts that can be shared. Therefore, it has to be re-developed every time the hardware architecture is changed. . On the other hand, in the control of sending and receiving information between nodes such as GMPLS, there are few parts that depend on the hardware architecture, so using a common control node model can avoid significant re-development. There is a possibility.

  In recent years, attention has been paid to the application of GMPLS technology to optical networks, and therefore, unified control using a common optical network control protocol has become possible, so that there are many parts that can be commonly used in optical network control software. Therefore, there is a need for means to make it possible to use it.

  The present invention has been made in such a background, and can be commonly used in software such as GMPLS for transmitting and receiving information between nodes and realizing network control regardless of the hardware implementation method. By setting the control node model of the optical node device and operating it in the control protocol between the optical node devices, the software is shared, and the hardware is associated with the management model An object of the present invention is to provide an optical network node monitoring and control device that realizes a common control node model by realizing actual hardware control, and can realize the efficiency of optical network device development. .

  The present invention is an optical network node monitoring and control device, and the present invention is characterized by means for classifying the configuration of an optical node device into functional blocks corresponding to the functions, and for each of the classified functional blocks. And a means for assigning a control node model which is control software set in advance.

  As a result, even when a wide variety of optical node devices are arranged in the optical network, these functions can be classified and an optimal control node model can be assigned. Therefore, the control node model of the optical node device that can be used in common regardless of the hardware implementation method is set, and the software is shared by operating it in the control protocol between nodes. In contrast, by implementing the actual hardware control by associating with the control node model, it is possible to realize common control software and improve the efficiency of optical network device development. .

  In addition, a correspondence table in which the functional blocks classified by the classifying unit and the control node model corresponding to the functional block are recorded for one or more optical node devices is provided, and the assigning unit functions based on the correspondence table. Means for assigning a control node model for each block may be provided. Thereby, the function classification process and the control node model assignment process can be performed efficiently (claim 2).

More specifically, as the control node model, an AP (Access that accepts a user (client) signal is used.
Point) part, OPT (Optical Path Termination) part that performs optical path termination processing, and OCP (Optical
Connection Point) unit, an OP-CC (Optical Path Cross Connection) unit that changes the optical connection state, an N (Network) -Port unit that multiplexes at least one optical path and connects to an adjacent node, and at least A (Access) -Port comprising a set of one AP, and the means for assigning is that the user (client) signal is coupled to the AP, the AP is connected to one OPT, the OPT is one AP and one Connected to the OCP, the N-Port is combined with at least one OCP, the OCP on the N-Port side is combined with one N-Port and one OP-CC, and the OCP on the AP side is one OP-CC Combined with one OPT, the OP-CC may comprise means for allocating one to exist within a node (claim 3).

  Another aspect of the present invention is a program. The feature of the present invention is that, when installed in an information processing apparatus, the configuration of the optical node apparatus is changed to a functional block corresponding to the function. A function corresponding to a node monitoring and control apparatus of an optical network having a function to classify and a function to assign a control node model which is control software set in advance for each classified functional block is realized ( Claim 4).

  In addition, the function corresponding to the correspondence table in which the function blocks classified by the function to be classified and the control node model corresponding to the function block are recorded for one or more optical node devices is realized, A function of assigning a control node model to each functional block based on the correspondence table can be realized (claim 5).

  More specifically, as the control node model, an AP unit that receives a user (client) signal, an OPT unit that performs optical path termination processing, an OCP unit that is a connection point of a cross connection, and an optical connection state are changed. As an assigning function, an OP-CC unit, an N-Port unit that multiplexes at least one optical path and connects to an adjacent node, and an A-Port composed of at least one AP are allocated. (Client) signal is coupled to AP, AP is connected to one OPT, OPT is connected to one AP and one OCP, N-Port is combined with at least one OCP, and OCP on the N-Port side Is combined with one N-Port and one OP-CC, and the OCP on the AP side is combined with one OP-CC and one OPT. CC is able to realize the function of assigning to lie one inside node (Claim 6).

  Still another aspect of the present invention is the information processing apparatus-readable recording medium on which the program of the present invention is recorded (claim 7). By recording the program of the present invention on the recording medium of the present invention, the information processing apparatus can install the program of the present invention using this recording medium. Alternatively, the program of the present invention can be directly installed on the information processing apparatus via a network from a server holding the program of the present invention.

  As a result, using a general-purpose information processing device, even if a wide variety of optical node devices are arranged in the optical network, the node monitoring control of the optical network can classify these functions and assign an optimal control node model. An apparatus can be realized.

  According to the present invention, a control node model of an optical node device that can be used in common regardless of a hardware implementation method is set, and the software is shared by operating the control protocol between optical node devices. By implementing the actual hardware control by associating the hardware with the management model, it is possible to realize common control software and improve the efficiency of optical network device development. Can be realized.

  The configuration of an optical network node monitoring control apparatus according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a configuration diagram of a node monitoring control apparatus according to the present embodiment. FIG. 2 is a diagram showing a correspondence table of this embodiment.

  The present embodiment is an optical network node monitoring and control apparatus, and this embodiment is characterized by means for classifying the configuration of the optical node apparatus into functional blocks corresponding to the functions, and the classified functional blocks. The hardware dependency absorbing function unit 3 is provided with means for assigning a control node model, which is control software set in advance, for each hardware (claim 1).

  Further, as shown in FIG. 2, a hardware-dependent absorption is provided, which includes a correspondence table in which functional blocks classified by the classifying unit and control node models corresponding to the functional blocks are recorded for one or more optical node devices. The function unit 3 includes means for assigning a control node model for each function block based on the correspondence table (claim 2).

  As the control node model, as shown in the correspondence table of FIG. 2, an AP unit that receives a user (client) signal, an OPT unit that performs optical path termination processing, an OCP unit that is a connection point of a cross connection, An OP-CC unit that changes the connection state of N, a N-Port unit that multiplexes at least one optical path and connects to an adjacent node, and an A-Port composed of at least one AP. Since A-Port is a set of APs, it is not recorded in the correspondence table (Claim 3).

  Based on this correspondence table, the hardware dependency absorption function unit 3 combines the user (client) signal with the AP, the AP is connected to one OPT, the OPT is connected to one AP and one OCP, and N-Port Is combined with at least one OCP, the OCP on the N-Port side is combined with one N-Port and one OP-CC, the OCP on the AP side is combined with one OP-CC and one OPT, and OP -CC comprises means for allocating one to exist in a node (Claim 3). The correspondence table is not shown in the configuration of FIG. 1, but is assumed to be provided in the hardware dependency absorption function unit 3 in this embodiment.

  The present invention can be implemented as a program that, when installed in a general-purpose information processing apparatus, causes the information processing apparatus to realize a function corresponding to the node monitoring control apparatus of the present invention (claims 4 to 6). This program is recorded on a recording medium and installed in the information processing apparatus (Claim 7), or installed in the information processing apparatus via a communication line, so that the information processing apparatus has the control protocol function unit 1 and the control. Functions corresponding to the classifying means, the assigning means, and the correspondence table of the node model function unit 2 and the hardware dependency absorption function unit 3 can be realized.

  Hereinafter, the present embodiment will be described in more detail.

  The node monitoring and control apparatus according to the present embodiment associates the control protocol function unit 1 such as GMPLS, the control node model function unit 2 operated by the control protocol, the control node model function unit 2 and the function of the optical node device. Assume that the hardware dependency absorption function unit 3 that executes the operation of the optical node device includes three functional units.

  FIG. 3 shows a control node model used in this embodiment. As shown in FIG. 3, the control node model of this embodiment includes an AP unit that receives a user (client) signal, an OPT unit that performs optical path termination processing, an OCP that is a cross-connection connection point, and an optical connection state. An OP-CC to be changed, an N-Port that multiplexes at least one optical path and connects to an adjacent node, and an A-Port including a set of at least one AP are provided.

  The user (client) signal is coupled to the AP, the AP is always connected to one OPT, and the OPT is always connected to one AP and one OCP. N-Port is combined with at least one OCP. The OCP on the N-Port side is combined with one N-Port and one OP-CC. The AP-side OCP is combined with one OP-CC and one OPT. Note that only one OP-CC exists in a node.

  In FIG. 3, two N-Ports and one A-Port are shown. However, the present invention is not limited to this, and generally has at least 0 N-Ports and at least 0 A-Ports. It only has to be. However, if both are zero, it does not make sense. In FIG. 3, two APs belong to the A-Port, but generally one or more APs only need to belong to the A-Port.

  FIG. 4 shows how the control node model of this embodiment is operated by the optical network control protocol. In this example, an example of RSVP-TE used as a signaling protocol in GMPLS as an optical network control protocol is shown. However, the description can be similarly applied to other signaling protocols (for example, CR-LDP (Constraint Based Routed-Label Distribution Protocol)) or P-NNI.

  An optical path setting protocol based on the RSVP-TE protocol will be briefly described. A Path message is sent from the Ingress node toward the destination. The Intermediate node that is the relay node relays the Path message. When the Egress node receives the Path message, it processes it and returns a Reserve message. At the Egress node, simultaneously with the reply, (1) AP and OPT are set, and (2) OCP cross connection is set. The Intermediate node that has received the Reserve message sets up (3) OCP cross connection. After receiving the Reserve message, the Ingress node performs (4) OCP cross connection setting and (5) AP and OPT setting. When all procedures are completed in this way, an optical path can be set (FIG. 10).

  In this way, an optical path could be logically set by operating the control node model. At this time, it was also shown that the cross-connect operation was performed in an idealized state regardless of whether the cross-connect operation was an OTU cross-connect or an ODU cross-connect.

  FIG. 2 shows an example of correspondence between the control node model and the logical models in the node configuration examples 1, 2, and 3. As shown in the figure, it was shown that the control node model of the present embodiment can be associated in all cases. Correspondence is possible even in the case of other configuration examples. In addition, since the optical cross-connect device can be controlled using individual logical models, it can be controlled in any case using the common control node model of the present embodiment that is associated. .

  The correspondence table shown in FIG. 2 is held by the hardware dependency absorption function unit 3, and the result of the operation of the common control node model can be used to control actual hardware based on this correspondence table.

  According to the present invention, node control software can be shared, and the development efficiency of an optical network device can be improved.

The block diagram of the node monitoring control apparatus of a present Example. The figure which shows the correspondence table of a present Example. The figure for demonstrating the control node model of a present Example. The figure for demonstrating operation of the control node model of a present Example. The figure which shows the apparatus structural example 1. FIG. FIG. 3 is a functional block diagram of configuration example 1; The figure which shows the apparatus structural example 2. FIG. The functional block diagram of the structural example 2. FIG. The figure which shows the apparatus structural example 3. FIG. 10 is a functional block diagram of configuration example 3. The figure which shows the relationship between the conventional node control software and hardware.

Explanation of symbols

1 Control protocol function part 2 Control node model function part 3 Hardware dependency absorption function part

Claims (7)

Means for classifying the configuration of the optical node device into functional blocks according to the function;
Means for allocating a control node model, which is control software set in advance for each of the classified functional blocks. Comprising a correspondence table in which functional blocks classified by the classifying means and control node models corresponding to the functional blocks are recorded for one or more optical node devices;
The optical network node monitoring and control apparatus according to claim 1, wherein the allocating means includes means for allocating a control node model for each functional block based on the correspondence table. As the control node model,
An AP (Access Point) unit that receives a user (client) signal;
OPT (Optical Path Termination) part that performs optical path termination processing;
OCP (Optical Connection), the connection point of the cross connection
Point)
OP-CC (Optical Path Cross) for changing the optical connection status
Connection) section,
N (Network) -Port unit that multiplexes at least one optical path and connects to an adjacent node;
A (Access) -Port consisting of a set of at least one AP,
The means for assigning is that a user (client) signal is coupled to an AP, the AP is coupled to one OPT, the OPT is coupled to one AP and one OCP, and the N-Port is coupled to at least one OCP; The OCP on the N-Port side is combined with one N-Port and one OP-CC, the OCP on the AP side is combined with one OP-CC and one OPT, and one OP-CC exists in the node The optical network node monitoring and control apparatus according to claim 1, further comprising means for allocating the optical network. By installing on an information processing device,
A function of classifying the configuration of the optical node device into functional blocks according to the function;
A program for realizing a function corresponding to a node monitoring and control apparatus of an optical network, which has a function of assigning a control node model which is control software set in advance for each classified functional block. Realizing a function corresponding to a correspondence table in which function blocks classified by the function to be classified for one or more optical node devices and a control node model corresponding to the function block are recorded;
The program according to claim 4, wherein a function for allocating a control node model for each functional block is realized based on the correspondence table as the function to be allocated. As the control node model,
An AP unit for receiving a user (client) signal;
An OPT unit for terminating the optical path;
An OCP part which is a connection point of a cross connection;
An OP-CC unit for changing the optical connection state;
An N-Port unit that multiplexes at least one optical path and connects to an adjacent node;
A-Port consisting of a set of at least one AP is realized,
As the assigning function, the user (client) signal is combined with the AP, the AP is connected with one OPT, the OPT is connected with one AP and one OCP, the N-Port is combined with at least one OCP, The OCP on the N-Port side is combined with one N-Port and one OP-CC, the OCP on the AP side is combined with one OP-CC and one OPT, and one OP-CC exists in the node The program according to claim 4, which realizes a function of allocating so that   7. A recording medium readable by the information processing apparatus on which the program according to claim 4 is recorded.

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