JP6167543B2 - Network management apparatus and communication path setting method - Google Patents

Description

  The present invention relates to a technique for managing a communication path in a communication network, and more particularly to a technique for setting an appropriate communication path according to the state of a transmission path or a signal.

  With the development of the information and communication society, the amount of communication has increased, and the importance of optical communication capable of large-capacity communication has increased. In addition, the social importance of information communication has increased, and there has been a strong demand for stable communication. In an optical communication network, communication using a wavelength division multiplexing (WDM) method may be performed. An optical communication network in which communication is performed by the wavelength division multiplexing method is configured by combining a transmission apparatus having a WXC (Wavelength Cross Connect) function and a transmission path using an optical fiber or the like. In the WXC function unit of each transmission device, recombination of the route of the signal input from each route is performed and output to each route, and the signal is transmitted to the target device by repeating it and information is transmitted. Is transmitted. In such an optical communication network, there are a plurality of signal paths to the target transmission device, and the signal route is recombined in each transmission device, so that the complexity of the network increases. Therefore, there is a high need for a technique for accurately setting a signal path in such a complex network. In addition, in optical communication networks, when a transmission device or transmission path is added or removed, maintenance is performed on an intermediate transmission device, or when a route is reset such as when a failure occurs, the signal route is quickly May be required to be settable. From such a background, development of a technique for setting a signal communication path in an optical communication network has been actively performed. As a technique related to a method for setting a signal communication path in an optical communication network, for example, a technique as disclosed in Patent Document 1 is disclosed.

  Patent Document 1 discloses a method for selecting an optimum route from a plurality of communication routes. Patent Document 1 shows a communication network having two paths between two transmission / reception devices. In Patent Document 1, the number of wavelengths used for each communication path, the number of relay devices, the distance of the transmission path, and the like are extracted, compared between the paths, and the optimal path of the two paths is determined as the signal communication path. Is selected.

  Patent Document 2 discloses a method for setting an optimum path from a plurality of paths in a communication system including a configuration in which three or more transmission paths are connected to other communication apparatuses. In Patent Document 2, elements such as a route distance and the number of alarms are set and weighted for each element to rank communication routes and extract candidates.

  Patent Document 3 discloses a technique for determining a communication path in a communication network including transmission apparatuses having a WXC function. In Patent Literature 3, when devices at both ends of a section for which a route is to be set are designated, route candidates are displayed on the screen. In Patent Document 3, by displaying candidate routes on the screen, the operator can select a candidate while visually grasping the candidate route, so that an operator's erroneous operation or the like can be prevented.

International Publication No. 2004/114554 JP 2002-368792 A JP 2012-156770 A

  However, the technique disclosed in Patent Document 1 has the following problems. In Patent Document 1, when setting a path, it is determined which of the two paths is suitable for communication based on information such as the distance of the transmission path and the number of relay devices. These pieces of information do not change after the communication network is installed unless there is an addition or removal of a device or the like. For this reason, even when a failure occurs in a certain transmission path and the signal strength decreases to hinder communication, a path unsuitable for use can be selected as a candidate. An operator needs to set a route in consideration of a route that is not suitable for use, and a complicated determination may be required. Therefore, Patent Document 1 is not sufficient as a technique used when it is desired to immediately set an alternative route when a failure occurs in a complex network. Similarly to Patent Document 1, Patent Document 2 is not based on the actual path state when setting a communication path, such as the distance of a path that does not change after installation and the number of alarms generated in a certain period of time. The route is set based on the information. Therefore, Patent Document 2 is not sufficient as a technique used for setting a route in consideration of a signal transmission / reception state and a transmission path state.

  In addition, Patent Document 3 makes it easy to see the route visually and reduces the burden on the operator when setting the route. However, in the selection of the displayed route candidate, the signal transmission / reception state, the state of the transmission route, etc. Not considered. Therefore, an operator needs to select a communication path while considering a transmission path that is not suitable for communication, which increases the burden on the operator.

  An object of the present invention is to obtain a network management apparatus capable of setting an optimum route by selecting route candidates based on a signal transmission / reception state, a transmission line state, and the like.

  In order to solve the above problems, the network management apparatus of the present invention includes an input unit, a monitoring unit, a determination unit, and a route setting unit. The input means receives a reference for selecting a signal path. The monitoring means collects information obtained by measuring the characteristics of the signal between the transmission apparatuses or the characteristics of the transmission path between the transmission apparatuses based on a criterion for selecting the path of the signal to obtain measurement result information. The path setting means sets the signal path based on the measurement result information collected by the monitoring means and a predetermined reference set in advance.

  In the communication path setting method of the present invention, a reference for selecting a signal path is input, and information on signal characteristics between transmission apparatuses or information on transmission path characteristics is used as a reference for selecting a signal path. Collected based on measurement result information. A signal path is set based on the collected measurement result information and a predetermined reference set in advance.

  In the present invention, since information of measurement results such as signal characteristics is collected and the communication path is set based on the result, it is possible to set an optimum path according to the state of the communication network. In addition, by collecting measurement results based on the criteria for selecting routes and setting routes based on the results, the optimal communication route can be reduced by reducing the burden on the operator even in complex communication networks. Can be selected.

It is a figure which shows the outline | summary of a structure of the 1st Embodiment of this invention. It is a figure which shows the structure of the apparatus of the 1st Embodiment of this invention. It is a figure which shows the structure of the apparatus of the 1st Embodiment of this invention. It is a figure which shows the structure of the apparatus of the 1st Embodiment of this invention. It is a figure which shows the structure of the apparatus of the 1st Embodiment of this invention. It is a figure which shows the example of the data in the 1st Embodiment of this invention. It is a figure which shows the example of the data in the 1st Embodiment of this invention. It is a figure which shows the example of the data in the 1st Embodiment of this invention. It is a figure which shows the example of the data in the 1st Embodiment of this invention. It is a figure which shows the example of the data in the 1st Embodiment of this invention. It is a figure which shows the example of the data in the 1st Embodiment of this invention. It is a figure which shows the outline | summary of a structure of the 2nd Embodiment of this invention. It is a figure which shows the structure of the apparatus of the 2nd Embodiment of this invention. It is a figure which shows the structure of the apparatus of the 3rd Embodiment of this invention.

  A first embodiment of the present invention will be described in detail with reference to FIG. FIG. 1 shows an outline of the configuration of a communication network system according to this embodiment. The communication network system of the present embodiment includes an NMS (Network Management System) server 10, a plurality of transmission devices, and transmission paths. The communication network system of the present embodiment includes four transmission apparatuses, and includes a first transmission apparatus 20, a second transmission apparatus 40, a third transmission apparatus 60, and a fourth transmission apparatus 80. ing. In the communication network system of the present embodiment, optical signal communication is performed using a wavelength division multiplexing (WDM) system. Each transmission apparatus is connected by a transmission path composed of an optical fiber or the like. In FIG. 1, the transmission path between the first transmission apparatus 20 and the third transmission apparatus 60 is f1-f3, the transmission path between the first transmission apparatus 20 and the fourth transmission apparatus 80 is f1-f4, A transmission path between the third transmission device 60 and the fourth transmission device 80 is denoted as f3-f4. Further, the transmission path between the third transmission apparatus 60 and the second transmission apparatus 40 is expressed as f3-f2, and the transmission path between the fourth transmission apparatus 80 and the second transmission apparatus 40 is expressed as f4-f2. ing.

  FIG. 2 shows an outline of the configuration of the NMS server 10. As shown in FIG. 2, the NMS server 10 includes a design concept receiving unit 11, a design concept DB (Database) 12, and a design concept calling / output display unit 13. The NMS server 10 further includes a measurement data extraction instruction unit 14, a measurement data collection DB 15, a route index calculation unit 16, a prioritization unit 17, and a route display unit 18. The NMS server 10 includes a manager 19 that transmits and receives information to and from the first transmission device 20.

  The design concept receiving unit 11 of the NMS server 10 has a function of receiving a design concept input by an operator and analyzing the input design concept. The design concept refers to a route setting policy and determination criteria for setting a communication route for an optical signal. The design concept receiving unit 11 has a function of decomposing the input design concept into predetermined units. For example, the design concept receiving unit 11 decomposes the input design concept for each word. When the design concept receiving unit 11 decomposes the design concept into words or the like, the design concept receiving unit 11 has a function of comparing the decomposed words and the like with data for each preset category to determine which class the decomposed word belongs to. The design concept receiving unit 11 associates the disassembled design concept for each design concept and outputs it to the design concept DB 12. The design concept DB 12 stores design concepts and the like sent from the design concept receiving unit 11. The design concept DB 12 has a function of sending design concept information to the measurement data extraction instruction unit 14 in response to a request from the design concept call / output display unit 13.

  The design concept call / output display unit 13 has a function of calling and displaying the design concept input by the operator in the past and stored in the design concept DB 12 from the design concept DB 12. The design concept call / output display unit 13 has a function of requesting the design concept selected by the operator to the design concept DB 12 and sending the design concept information to the measurement data extraction instruction unit 14. When receiving the design concept information stored in the design concept DB 12, the measurement data extraction instruction unit 14 has a function of determining the measurement items to be collected for each classified design concept item and the location from which the measurement items are acquired. Have. When the measurement data extraction instruction unit 14 determines the measurement item to be collected and the measurement location, the measurement data extraction instruction unit 14 instructs the measurement data collection DB 15 to extract the measurement data. The measurement data extraction instruction unit 14 has a function of determining measurement items and measurement locations for collecting measurement data corresponding to the design concept when receiving information on the newly input design concept. When the measurement data extraction instruction unit 14 determines the measurement item and the measurement location corresponding to the newly collected measurement data, the measurement data extraction instruction unit 14 sends information on the measurement item and the measurement location to the manager unit 19.

  The measurement data collection DB 15 has a function of storing measurement data for each transmission device or each transmission path received via the manager unit 19. When the measurement data collection DB 15 receives an instruction to extract measurement data from the measurement data extraction instruction unit 14, the measurement data collection DB 15 outputs measurement data necessary for route calculation to the route index calculation unit 16. The path index calculation unit 16 receives the measurement data output from the measurement data collection DB 15, and calculates and prioritizes an index for comparing the characteristics of each transmission path and signal between the transmission devices based on the measurement data. To the unit 17. The index can be calculated by a predetermined calculation method set in advance, or can be calculated as a ratio of measurement data of each transmission line to a predetermined reference value in comparison with a predetermined reference value. In addition, the index can be calculated by comparing measured values for each transmission path, and can be calculated as a relative value for other transmission paths. In addition, when the measurement data is out of the predetermined set value range, the path index calculation unit 16 may determine that the transmission device or transmission path to which the measurement data corresponds is not suitable for communication. The prioritization unit 17 calculates the priority of each route from the index data received from the route index calculation unit 16 and outputs the priority data to the route display unit 18. The route display unit 18 has a function of setting and displaying priority orders for communication route candidates based on the priority data output from the priority assigning unit 17. The Manager unit 19 has a function of transmitting / receiving information to / from each transmission device via the first transmission device 10. The Manager unit 19 has a function of transmitting / receiving information to / from each transmission device via the first transmission device 10. The Manager unit 19 transmits information on the measurement items and measurement locations of the measurement data sent from the measurement data extraction instruction unit 14 to each transmission device. The Manager unit 19 sends measurement data sent from each transmission device to the measurement data collection DB 15. In addition, it has a function of transmitting and receiving information relating to the setting of the communication network system and information relating to the operating status of the transmission apparatus.

  The configuration of the first transmission device 20 will be described with reference to FIG. FIG. 3 shows an outline of the configuration of the first transmission apparatus 20. The first transmission device 20 includes a WXC (Wavelength Cross Connect) unit 21, a transmission optical amplifier 22, a reception optical amplifier 23, a multiplexing unit 24, and a separation unit 25. The first transmission device 20 includes a first transponder 26, a second transponder 27, an OSC (Optical Supervisor Channel) unit 28, a transmission signal measurement unit 29, a reception signal measurement unit 30, and an agent unit 31. It has more. Inserted into the WXC unit 21 from signals transmitted from the third transmission device 60 and the fourth transmission device 80 via the transmission path, and from information devices and communication facilities connected to the first transmission device 20 ( A client signal to be added) is input. The signals input to the WXC unit 21 are separated for each channel. The separated signal is divided for each channel and sent to a route to a predetermined route. The signal sent to the predetermined route is multiplexed for each route and output to the transmission route to the third transmission device 60 or the fourth transmission device 80, or dropped and dropped. 1 is output as a client signal to an information device or a communication facility connected to one transmission device 20.

  The transmission optical amplifier 22 amplifies the optical signal output from the WXC unit 21 and sends it to the transmission line. The receiving optical amplifier 23 amplifies the optical signal input from the transmission path and sends it to the WXC unit 21. As the transmission optical amplifier 22 and the reception optical amplifier 23, for example, an erbium-doped fiber amplifier can be used.

  The multiplexing unit 24 multiplexes the signal converted into the optical signal by the first transponder 26 by the multiplexing element and outputs the multiplexed signal to the WXC unit 21. In the separation unit 25, the signal branched and output by the WXC unit 21 is separated for each channel by a demultiplexing element, and is output to a path to a predetermined second transponder 27. As the multiplexing element and the demultiplexing element, for example, an arrayed waveguide diffraction grating can be used. The first transponder 26 includes a semiconductor laser and has a function of converting each channel signal into an optical signal having a predetermined wavelength. The second transponder 27 includes a photodiode as a light receiving element, converts an input optical signal into an electrical signal, and outputs the electrical signal.

  The OSC unit 28 controls transmission / reception of OSC signals transmitted / received between transmission apparatuses. The OSC unit 28 outputs the device status and setting information of the first transmission device 20 and transmits it to other transmission devices via the WXC unit 21. The OSC unit 28 outputs data such as device status received from other transmission devices to the management terminal and the Agent unit 31 connected to the first transmission device 20. The OSC unit 28 has a function of receiving measurement data from the transmission signal measurement unit 29 and the reception signal measurement unit 30 and sending the measurement data to another transmission apparatus or the Agent unit 31. Further, the OSC unit 28 has a function of sending information requesting measurement data received via the Agent unit 31 to another transmission device via the WXC unit 21, and a function of sending information to the transmission signal measuring unit 29 or the received signal measuring unit 30. Have

  The transmission signal measuring unit 29 has a function of monitoring the transmission state of the optical signal at the output unit of the transmission optical amplifier 22. The reception signal measuring unit 30 has a function of monitoring the reception state of the optical signal at the input unit to the reception optical amplifier 23. The transmission signal measurement unit 29 and the reception signal measurement unit 30 measure signal characteristics such as the intensity of the optical signal, the signal-to-noise ratio (SNR), and the error rate. The transmission signal measurement unit 29 and the reception signal measurement unit 30 may measure transmission path characteristics such as transmission path span loss. Span loss refers to the transmission loss of the transmission line, and is calculated by comparing the result of measurement of the output intensity at the transmission apparatus facing through the transmission line with the result of receiving the OSC signal and the intensity of the received signal measured by the own apparatus. Is done. Further, monitoring by monitoring signal characteristics or a monitoring result may be referred to as PM (Performance Monitor). The measurement is performed by measuring a signal in a band used for communication as a main signal. Measurement data indicating measurement results in the transmission signal measurement unit 29 and the reception signal measurement unit 30 are output to the OSC unit 28, respectively.

  The Agent unit 31 has a function of transmitting information such as the device status of the own device or other transmission device sent from the OSC unit 28 or measurement data to the NMS server 10. Further, the Agent unit 31 has a function of sending information related to control such as communication network setting information sent from the NMS server 10 and a request for measurement data such as signal characteristics to the OSC unit 28.

  The configuration of the second transmission device 40 will be described with reference to FIG. FIG. 4 shows an outline of the configuration of the second transmission device 40. The second transmission device 40 includes a WXC unit 41, a transmission optical amplifier 42, a reception optical amplifier 43, a multiplexing unit 44, and a separation unit 45. The second transmission device 40 further includes a first transponder 46, a second transponder 47, an OSC unit 48, a transmission signal measurement unit 49, and a reception signal measurement unit 50. The WXC unit 41, the transmission optical amplifier 42, the reception optical amplifier 43, the multiplexing unit 44, the separation unit 45, the first transponder 46, the second transponder 47, the transmission signal measurement unit 49, and the reception signal measurement unit 50 A transmission device 20 having the same name, configuration, and function can be used. The OSC unit 48 has a function of receiving measurement data information indicating the measurement results measured by the transmission signal measurement unit 49 and the reception signal measurement unit 50, outputting the information via the WXC unit 41, and sending it to the first transmission device 20. Have. In addition, it has a function of sending information such as measurement items and measurement points sent from the first transmission device 20 to the transmission signal measurement unit 49 and the reception signal measurement unit 50.

  The configuration of the third transmission device 60 will be described with reference to FIG. FIG. 5 shows an outline of the configuration of the third transmission device 60. The third transmission device 60 is connected to the first transmission device 20, the second transmission device 40, and the fourth transmission device 80 via a transmission path.

  The third transmission device 60 includes a first WXC unit 61, a transmission optical amplifier 62, a reception optical amplifier 63, a multiplexing unit 64, and a separation unit 65. The third transmission device 60 further includes a first transponder 66, a second transponder 67, a first OSC unit 68, a transmission signal measurement unit 69, and a reception signal measurement unit 70. The third transmission device 60 further includes a second WXC unit 71 and a second OSC unit 72. The transmission optical amplifier 62, the reception optical amplifier 63, the multiplexing unit 64, the separation unit 65, the first transponder 66, the second transponder 67, the transmission signal measurement unit 69, and the reception signal measurement unit 70 are the first transmission device 20. Those having the same structure and function as the parts having the same names can be used.

  The first WXC unit 61 has the same function as the WXC unit 21 of the first transmission device 20, and also a function of rearranging the signal paths for signals that are input to and output from the second WXC unit 71. Have The first WXC unit 61 sends a signal sent from the second WXC unit 71 to a predetermined transmission path or a path branched to an information device or communication facility connected to the third transmission device 60. And a function for sorting and outputting. In addition, the first WXC unit 61 transmits a signal of a predetermined channel among signals input from the transmission path and signals inserted from the information device and communication equipment in the third transmission device 60 to the second WXC unit 71. Has the function to send.

  The second WXC unit 71 has a function of transmitting a signal input from the transmission path to another transmission path or the first WXC unit 61. In the present embodiment, the first WXC unit 61 is connected to the first transmission device 20 via the transmission line f1-f3 and the second transmission device 40 via the transmission line f3-f2. . Further, it is assumed that the second WXC unit 71 is connected to the fourth transmission device 80 via the transmission line f3-f4. Since the second WXC unit 71 has only one other transmission device connected via the transmission line, a signal input from the transmission line is sent to the first WXC unit 61. Further, the second WXC unit 71 has a function of outputting a signal sent from the first WXC unit 61 to a predetermined route. In the present embodiment, the second WXC unit 71 has one other transmission device connected via the transmission path, and therefore the signal transmitted from the first WXC unit 61 is the fourth transmission device 80. To the transmission line f3-f4.

  The fourth transmission device 80 may have the same configuration and function as the third transmission device 60. The fourth transmission device 80 is connected to the first transmission device 20, the second transmission device 40, and the third transmission device 60 via a transmission path.

  An operation when the design concept is set in the communication network system of the present embodiment will be described. An operator, that is, an operator, inputs a design concept into the NMS server 10. When the operator inputs the design concept, the input sentences are numbered as in the design concept 1 and temporarily stored in the design concept receiving unit 11. For example, when the operator inputs “I want to increase the OSNR at NE2”, “I want to increase the OSNR at NE2” is stored as the design concept 1. The NE of “NE2” indicates the transmission apparatus, and “NE2” indicates the second transmission apparatus 40. OSNR indicates an optical signal-to-noise ratio. FIG. 6 shows an example in which six design concepts are input and stored as design concepts 1 to 6.

  The design concept receiving unit 11 decomposes the temporarily stored design concept into terms of a predetermined unit. For example, the design concept receiving unit 11 decomposes a design concept input as a sentence into words of a predetermined unit by a morphological analysis method or the like. When the inputted design concept is decomposed into words, the design concept receiving unit 11 determines which category, that is, which category the decomposed word belongs to. In this embodiment, three categories are set as predetermined classifications. The three categories of the present embodiment are classified as to which transmission device is related, what parameters are, and how it is desirable. For example, words such as “NE1” and “NE2” shown in FIG. In addition, the category relating to the parameters corresponds to words relating to items to be actually measured, such as “OSNR”, “span loss”, “OPR fluctuation”, and “white noise” as shown in FIG. OPR indicates the strength of the received signal. In addition, the category of how you want to do includes words related to the directionality of characteristics such as “Large”, “Small”, “Minimum”, “Equal”, etc. as shown in FIG. Are classified. Words belonging to each category are stored in advance as data as shown in FIGS. The design concept receiving unit 11 compares the data stored in advance for each category with the decomposed word to determine which category it belongs to.

  When a sentence such as the design concept 1 is input, the design concept receiving unit 11 decomposes into “NE2”, “OSNR”, and “large”. If the design concept receiving unit 11 determines that “in NE2” is included in the data indicating which transmission device is related to FIG. 7 or similar to it, the design concept receiving unit 11 classifies the category. To do. When the design concept receiving unit 11 classifies the words included in the input design concept into categories, the design concept receiving unit 11 stores the result of classification in the design concept DB 12. FIG. 10 shows an example in which words included for each design concept are classified and stored in the design concept DB 12. As shown in FIG. 10, the input sentences are associated with the numbers assigned to the design concepts, and the input sentences are classified into categories for each word and stored.

  When a new design concept is stored in the design concept DB 12, the newly stored design concept data is sent to the measurement data extraction instruction unit 14 via the design concept call / output display unit 13. When the measurement data extraction instruction unit 14 receives the data of the newly stored design concept, the measurement data extraction instruction unit 14 determines the measurement item and the measurement location of the measurement data corresponding to the newly stored design concept. When the measurement data extraction instruction unit 14 determines the measurement item and the measurement location of the measurement data, the measurement data extraction instruction unit 14 sends the measurement data measurement item and measurement location information corresponding to the newly stored design concept to the manager unit 19. When the manager 19 receives the information on the measurement item and the measurement location, the manager 19 sends information requesting the corresponding measurement data to each transmission device via the first transmission device 20. Each transmission device that has received information requesting measurement data measures the corresponding measurement item at the corresponding measurement location, and transmits measurement data indicating the measurement result to the NMS server 10 via the first transmission device 20. To do.

  When acquiring measurement data in each transmission device, if the measurement data is data acquired for each wavelength, measurement is performed on a signal of a channel corresponding to a predetermined wavelength. When signal communication is not performed on a channel corresponding to a predetermined wavelength, measurement is performed on a channel close to a channel including the predetermined wavelength among channels used for communication. The predetermined wavelength is set, for example, as the central wavelength of the entire band used as the main signal in the communication network system. A method may be used in which measurement is performed by setting a plurality of predetermined wavelengths, and an average value obtained by measurement at a plurality of wavelengths is used as measurement data. In addition, it is also possible to set a correction value by measuring a characteristic difference for each wavelength in advance at the time of installation of a transmission apparatus or a transmission path, and to perform correction when measurement data is collected at different wavelengths.

  When the manager 19 of the NMS server 10 receives the measurement data, it sends the measurement data to the measurement data collection DB 15. When the measurement data collection DB 15 receives the measurement data, the measurement data collection DB 15 stores it for each measurement item and measurement location. In addition, each transmission device reacquires measurement data at regular intervals, and transmits the measurement data to the NMS server 10 via the first transmission device 20. The measurement data collection DB 15 stores measurement data for every fixed time measured from that time point to a predetermined period before. Therefore, the information stored in the measurement data collection DB 15 is data that has a high possibility of reflecting the latest signal state and transmission path state in the communication network system, and has high data reliability. Further, a method of requesting re-acquisition of measurement data from the NMS server 10 to each transmission apparatus may be employed.

  An operation when signal communication path setting, that is, path setting is performed in the communication network system of the present embodiment will be described. It is assumed that a communication route setting start operation is performed by an operator. The design concept call / output display unit 13 of the NMS server 10 requests design concept data from the design concept DB 12. When the design concept DB 12 receives a request for design concept data, the design concept DB 12 outputs the stored design concept to the design concept call / output display unit 13. Upon receiving the design concept data, the design concept call / output display unit 13 displays the design concept and shows it to the operator. When the operator selects one or more of the displayed design concepts and inputs the result, the design concept call / output display unit 13 sends the selection result to the measurement data extraction instruction unit 14.

  When the measurement data extraction instruction unit 14 receives information on the design concept selected by the operator from among those already stored, the measurement data extraction instruction unit 14 determines measurement data corresponding to the design concept. When the measurement data extraction instruction unit 14 determines necessary measurement data, the measurement data extraction instruction unit 14 sends an instruction to extract measurement data to the measurement data collection DB 15. For example, if the operator has selected the design concept 1, the measurement data extraction instruction unit 14 determines the OSNR of each transmission path between the first transmission device 20 and the second transmission device 40, that is, the optical SN ratio. It is determined that measurement data is necessary, and information is sent to the measurement data collection DB 15.

  Upon receiving the necessary measurement data information from the measurement data extraction instruction unit 14, the measurement data collection DB 15 outputs the corresponding measurement data to the path index calculation unit 16. The route index calculation unit 16 calculates an index based on the measurement data, and outputs the index data to the prioritization unit 17. The index calculation method is set in advance according to each word in the category of what parameters are used. For example, when the operator selects the design concept 1, the path index calculation unit 16 is set to calculate index data as a noise figure based on measurement data of the optical S / N ratio on the transmission side and reception side of each transmission path. ing. The noise figure in the transmission line can be calculated as NF = SNRin / SNRout, where NF is the noise figure, SNRin is the optical SN ratio on the transmitting side, and SNRout is the optical SN ratio on the receiving side. SNRin, which is the optical S / N ratio on the transmission side, is measured by the transmission signal measuring unit of the transmission apparatus on the transmission side. The SNRout, which is the optical SN ratio on the receiving side, is measured by the received signal measuring unit of the transmission device on the receiving side. Further, the index data can be a ratio of values such as measurement data based on a predetermined reference value. The index data can also be generated by determining a corresponding rank by comparing with measured data or data in which a specific value such as a noise figure calculated from the measured value is ranked according to the value.

  The prioritizing unit 17 determines the priority order for each route based on the index data, adds it to the information indicating the route as the priority, and outputs it to the route display unit 18. When the route display unit 18 receives information indicating the route to which the priority is added, the route display unit 18 displays the route together with the priority of each route. Based on the displayed route and priority, the operator can select a route that is actually set as a signal route.

  An example in which when the design concept 1 is selected, the design index calculation unit 16 and the prioritization unit 17 calculate the index from the measurement data and determine the priority will be described. In the communication network system of the present embodiment, there are four communication paths from the first transmission device 20 to the second transmission device 40. The first of the four communication paths passes through the transmission path f1-f3, the third transmission device 60, and the transmission path f3-f2. In this embodiment, it will be referred to as a first route. The second of the four communication paths passes through the transmission path f1-f4, the fourth transmission device 80, and the transmission path f4-f2, and is referred to as a second path. The third one passes through the transmission path f1-f3, the third transmission apparatus 60, the transmission path f3-f4, the fourth transmission apparatus 80, and the transmission path f4-f2, in order, and is referred to as a third path. To do. The fourth one passes through the transmission path f1-f4, the fourth transmission apparatus 80, the transmission path f3-f4, the third transmission apparatus 60, and the transmission path f3-f2, in order, and is referred to as a fourth path. To do.

  Design concept 1 is to increase the optical SN ratio up to NE2, that is, the second transmission device 40. Therefore, the measurement data collection DB 15 outputs the measurement data of the optical SN ratio on the transmission side and the output side of each transmission path included in the candidate path to the calculation unit 16. When the design index calculation unit 16 receives the measurement data from the measurement data collection DB 15, the design index calculation unit 16 calculates a noise figure based on the measurement data of the optical signal-to-noise ratio of the transmission side signal and the output side signal of each transmission path to obtain index data. The index data can also be calculated as a ratio of noise figure to a predetermined reference value. As the predetermined reference value, a preset value, an average value of the noise figure of each transmission path, or a minimum value among noise figure data of each transmission path can be used. When the design index calculation unit 16 calculates the noise figure of each transmission path as an index, the design index calculation unit 16 sends the calculated index data to the prioritization unit 17 as index data.

  Upon receiving the index data, the prioritizing unit 17 obtains the total value of the index data of each transmission path included in each route for the first route to the fourth route. For example, in the case of the first route, the total value of the index data of the transmission lines f1-f3 and f3-f2 is obtained. When the prioritization unit 17 calculates the total value of the index data of the four paths, each path is in the order in which the average value of the index data is larger, that is, the smaller the noise figure is higher and the total value is higher. Prioritize Assuming that the fourth route, the second route, the first route, and the third route are in order from the smallest total value, the prioritization unit 17 sets the fourth route to the first, the second route to the second, Priorities are set in order of the route 3 and the third route 4. When the priority setting unit 17 sets the priority, the priority setting unit 17 outputs the priority data to the route display unit 18. When the route display unit 18 receives the priority data, the route display unit 18 displays the routes in order from the route with the highest priority to the worker. At that time, the route display unit 18 can also display information on transmission paths and transmission devices on each path. FIG. 11 shows an example in which the priority of each route, the route name, and the transmission device and transmission route data included in each route are combined. In the present embodiment, the noise figure is described as an example, but the same method can be used when other measurement data such as span loss is used. In the case of span loss, the higher the one with the smaller loss, the index is the span loss data obtained from the difference in signal strength between the transmission side and the reception side in each transmission path or the value obtained from the predetermined reference value and span loss data. The priority is set so that

  In this embodiment, when the operator selects a design concept from the stored design concepts, the design concept can be newly input and set. When the design concept is newly input and set, corresponding measurement data is collected in the same manner as when the design concept is newly input when the design concept is set in advance.

  In the communication network system according to the present embodiment, the NMS server 10 determines measurement items and measurement locations of signal characteristics and transmission path characteristics between transmission apparatuses based on the design concept, and requests measurement from each transmission apparatus. Collecting data. The NMS server 10 calculates an index such as a transmission path between the transmission apparatuses based on the measurement data, and displays the path by determining the priority order of the communication path based on the index. By adopting such a configuration, it is possible to select an optimal communication path candidate that has been given priority based on the inputted design concept. Therefore, in the communication network system according to the present embodiment, it is possible to select an optimum communication path using the priority order determined based on the measurement data indicating the status of the device, the transmission path, and the like. In addition, by selecting from the communication paths that are prioritized based on the input criteria, the optimal communication path can be reduced while reducing the burden on the operator when setting the communication path even in a complex communication network. Can be set.

  A second embodiment of the present invention will be described in detail with reference to FIG. FIG. 12 shows an outline of the configuration of the communication network system of this embodiment. The communication network system of this embodiment has the same configuration as that of the first embodiment. The communication network system according to the first embodiment obtains each measurement data by measurement in the band of the main signal. The communication network system according to the present embodiment collects measurement data by measuring a communication management signal such as an OSC signal and determines the priority of a path when main signal communication is not performed. It is used as measurement data that is the basis of In the communication network system of the present embodiment, it is possible to determine the state of the transmission path and the like before performing communication of the main signal by measuring the OSC signal and the like.

  The communication network system of this embodiment includes an NMS server 100, a first transmission device 91, a second transmission device 92, a third transmission device 93, and a fourth transmission device 94. Each transmission apparatus is connected to each other via a transmission path composed of an optical fiber or the like. Further, the NMS server 100 and the first transmission device 91 are connected to each other and have a function of transmitting / receiving a communication management signal such as an OSC signal. In the communication network system of the present embodiment, optical signal communication is performed using the wavelength division multiplexing method.

  The first transmission device 91, the second transmission device 92, the third transmission device 93, and the fourth transmission device 94 should have the same configuration as the transmission device with the same name in the first embodiment. it can. When the OSC unit of each transmission apparatus according to the present embodiment receives information on measurement items and measurement locations from the NMS server 100, the OSC unit has a function of transmitting the information to the transmission signal measurement unit and the reception signal measurement unit of the own apparatus. In addition, when the measurement data is received from the transmission signal measurement unit and the reception signal measurement unit of the own device, the OSC unit of each transmission device has a function of sending it to the first transmission device 91. A signal having a wavelength outside the wavelength band used for the main signal is used for the OSC signal. Measurement data when signals are measured in each transmission device is sent to the OSC unit, and is sent to the NMS server 100 via the first transmission device 91.

  An outline of the configuration of the NMS server 100 is shown in FIG. As shown in FIG. 13, the NMS server 100 of this embodiment is configured by the same parts as the NMS server 10 of the first embodiment. That is, the NMS server 100 includes a design concept reception unit 101, a design concept DB 102, and a design concept call / output display unit 103. The NMS server 100 further includes a measurement data extraction instruction unit 104, a measurement data collection DB 105, a route index calculation unit 106, a prioritization unit 107, and a route display unit 108. The NMS server 100 also includes a manager 109 that transmits and receives information to and from the first transmission apparatus 91.

  The design concept receiving unit 101, the design concept DB 102, the design concept calling / output display unit 103, and the manager unit 109 of the NMS server 100 have the same functions as the parts having the same names in the first embodiment.

  The measurement data extraction instruction unit 104 has a function of determining a corresponding measurement item and measurement location when receiving data of a new design concept. The measurement data extraction instruction unit 104 has a function of determining whether a corresponding measurement location is used for communication with reference to information on communication control of the NMS server 100 when determining a measurement item or measurement location. . When the measurement location is used for communication, the measurement data extraction instruction unit 104 sends information requesting the measurement data obtained by measuring the main signal to the transmission unit 109 to each transmission device. When the communication location is not used for communication, the measurement data extraction instruction unit 104 sends information for requesting the measurement data obtained by measuring the OSC signal to each transmission device to the manager unit 109. When the measurement data extraction instruction unit 104 receives the design concept information selected by the operator from the design concept call / output display unit 103, the measurement data extraction instruction unit 104 determines the measurement data to be collected set for each design concept item. It has the function to do. When the measurement data extraction instruction unit 104 determines the measurement data to be collected, it instructs the measurement data collection DB 105 to extract the measurement data.

  The measurement data collection DB 105 has a function of storing measurement data received from each transmission device via the manager unit 109. When the measurement data collection DB 105 receives the measurement data obtained by measuring the OSC signal, the measurement data collection DB 105 adds the information indicating that the OSC signal has been measured and stores the measurement data. When the measurement data collection DB 105 receives an instruction to extract measurement data from the measurement data extraction instruction unit 104, the measurement data collection DB 105 outputs measurement data necessary for route calculation to the route index calculation unit 106. The route index calculation unit 106 and the prioritization unit 107 have the same functions as the parts having the same names in the first embodiment. In addition, when the path index calculation unit 106 and the prioritization unit 107 perform generation of index data and determination of priority based on measurement data obtained by measuring the OSC signal, information indicating that is added to the subsequent part. It further has a function of outputting information. The route display unit 108 has the same function as the route display unit of the first embodiment. Also, the route display unit 108 has a function of displaying communication path candidates in response to the priority information based on the OSC signal measurement data from the priority assigning unit 107.

  The operation when a design concept is newly input and classified and stored in the design concept DB 102 in the communication network system of the present embodiment is the same as that of the first embodiment. Next, in this embodiment, an operation when collecting measurement data used for determination of priority based on the design concept stored in the design concept DB 102 will be described.

  It is assumed that a new design concept is input to the design concept receiving unit 101 and stored in the design concept DB 102. The design concept data newly stored in the design concept DB 102 is sent to the measurement data extraction instruction unit 104 via the design concept call / output display unit 103. When the measurement data extraction instruction unit 104 receives the newly stored design concept data, the measurement data extraction instruction unit 104 determines the measurement item of the measurement data corresponding to the newly stored design concept and the measurement location where the measurement data is measured. When the measurement data extraction instruction unit 104 determines the measurement item and the measurement location, the measurement data extraction instruction unit 104 determines whether the corresponding measurement location is used for communication of the main signal. Whether or not the main signal is used for communication is determined by referring to the network design information and operation information that the NMS server 100 has for communication management. When the measurement data extraction instruction unit 104 determines that the corresponding measurement location is used for communication of the main signal, the transmission data is added to each transmission device by adding information that the measurement data is collected by measuring the main signal. Information for requesting measurement data is sent to the manager 109. When the measurement data extraction instructing unit 104 determines that the corresponding measurement location is not used for communication of the main signal, the transmission data is added to each transmission device by adding information that the measurement data is collected by measuring the OSC signal. Information for requesting measurement data is sent to the manager 109.

  When the manager unit 109 receives information requesting measurement data from the measurement data extraction instruction unit 104, the manager unit 109 sends information requesting measurement data at the corresponding measurement location to each transmission device via the first transmission device 91. . Each transmission device that has received information requesting measurement data performs measurement of a measurement item designated at the corresponding measurement location by measuring a main signal or an OSC signal. When each transmission apparatus performs measurement, it transmits measurement data indicating the measurement result to the NMS server 100 via the first transmission apparatus 91. When the OSC signal is measured, the OSC signal is used to transfer information on the start and end of signal transmission / reception between the corresponding transmission apparatuses. When the manager unit 109 of the NMS server 100 receives the measurement data, it sends the measurement data to the measurement data collection DB 105. When the measurement data collection DB 105 receives the measurement data, the measurement data collection DB 105 stores it for each measurement location and measurement item. When the measurement data collection DB 105 receives the measurement data obtained by measuring the OSC signal, the measurement data collection DB 105 adds information indicating that and stores the measurement data. In addition, each transmission apparatus reacquires measurement data at regular time intervals and transmits the measurement data to the NMS server 100 via the first transmission apparatus 91. When the transmission / reception of the main signal is started when the measurement is repeated at regular time intervals, the measurement data may be acquired by measuring the main signal and sent to the NMS server 100. By updating the measurement data at regular time intervals or the like, the information stored in the measurement data collection DB 105 reflects the status of signals and transmission paths in the latest communication network system. Further, a method of requesting re-acquisition of measurement data from the NMS server 100 to each transmission apparatus may be adopted.

  An operation when signal communication path setting, that is, path setting is performed in the communication network system of the present embodiment will be described. It is assumed that a communication route setting start operation is performed by an operator. The design concept call / output display unit 103 of the NMS server 100 requests design concept data from the design concept DB 102. When the design concept DB 102 receives a request for design concept data, the design concept DB 102 outputs the stored design concept to the design concept call / output display unit 103. When the design concept call / output display unit 103 receives design concept data, the design concept is displayed and displayed to the operator. When the operator selects one or more of the displayed design concepts and inputs the result, the design concept call / output display unit 103 sends the selection result to the measurement data extraction instruction unit 104. When the measurement data extraction instruction unit 104 receives the design concept information input by the operator, the measurement data extraction instruction unit 104 determines measurement data corresponding to the design concept. When the measurement data extraction instruction unit 104 determines necessary measurement data, the measurement data extraction instruction unit 104 sends an instruction to extract measurement data to the measurement data collection DB 105.

  When the measurement data collection DB 105 receives necessary measurement data information from the measurement data extraction instruction unit 104, the measurement data collection DB 105 outputs the corresponding measurement data to the path index calculation unit 106. At that time, if the measurement data is measurement data obtained by measuring the OSC signal, information indicating that the OSC signal is measured is added to the measurement data. The route index calculation unit 106 calculates an index based on the measurement data, and outputs the index data to the prioritization unit 107. In the case of measurement data obtained by measuring the OSC signal, information indicating that is added to the index data and output.

  The prioritizing unit 107 determines the priority order for each route based on the index data, adds the priority as information indicating the route, and outputs the information to the route display unit 108. At this time, when an index based on measurement data obtained by measuring the OSC signal is used in a part of the route, the priority of the route can be lowered and displayed. When the OSC signal is used for display with a lower priority, a predetermined correction value set in advance is added when calculating the index, and index data is generated. When the route display unit 108 receives the information indicating the route, the route display unit 108 displays the route together with the priority of each route. The operator can select a communication path to be set as a signal path based on the displayed path and priority.

  In the communication network system of the present invention, as in the first embodiment, the NMS server 100 determines the measurement points and items of signal characteristics and transmission path characteristics between transmission apparatuses based on the design concept, and each transmission apparatus To collect the measurement results. When the NMS server 100 collects the measurement results, the NMS server 100 determines whether or not the location where the measurement is performed is used for main signal communication. By measuring the OSC signal when it is not used for communication of the main signal, a newly installed transmission device or a route passing through the transmission line can be a candidate for selecting a communication route. Further, since the priority is determined by measuring the OSC signal, it is possible to prioritize and set the communication path even for a path including a portion where the main signal is not communicated. . Therefore, in the present embodiment, even when a transmission device or a transmission path is newly installed or when recombination is performed, it is possible to select an optimal communication path according to the state of the device, the transmission path, or the like. In addition, by selecting from the communication paths that are prioritized based on the input criteria, the optimal communication path can be reduced while reducing the burden on the operator when setting the communication path even in a complex communication network. Can be set.

  In the first embodiment and the second embodiment, when an operator inputs or selects a design concept, the setting of the communication path is started, but the method is automatically started according to a predetermined condition. You can also For example, it is possible to adopt a method in which setting is automatically started upon detection of a change in the configuration of a transmission device and a transmission line in a communication network or a new installation. In addition, when the measurement data of the location where the main signal is communicated becomes a value outside the predetermined range, a method of presenting a warning of the occurrence of a failure, a method of starting the setting of a new communication path, You can also

  In the first embodiment and the second embodiment, the measurement data may be collected based on the wavelength of the signal for setting the communication path. In that case, the measurement data extraction instruction unit of the NMS server adds the wavelength of the signal input by the user or the wavelength set to be acquired in advance, and sends information requesting the measurement data to the Manager unit. And send. When setting the path, the measurement data extraction instruction unit adds the wavelength data to the necessary measurement data information and sends it to the measurement data collection DB. The measurement data collection DB stores the measurement data and the wavelength at which the measurement was performed in association with each other, and outputs the measurement data to the path index calculation unit upon request.

  A third embodiment will be described in detail with reference to FIG. FIG. 14 shows an outline of the configuration of the network management apparatus of this embodiment. The network management apparatus according to the present embodiment includes an input unit 111, a monitoring unit 112, and a route setting unit 113. The input means 111 receives a reference for selecting a signal path. The monitoring unit 112 collects information obtained by measuring the characteristics of the signal between the transmission apparatuses or the characteristics of the transmission path between the transmission apparatuses on the basis of the criterion for selecting the path of the signal to obtain measurement result information. The path setting unit 113 sets a signal path based on the measurement result information collected by the monitoring unit 112 and a predetermined reference set in advance.

  The network management device according to the present embodiment collects measurement results at a location where measurement is performed based on a reference for selecting a route of the input signal. The communication path is set based on the measurement result. By setting the communication path in this way, it is possible to set an optimum path according to the state of the communication network. In addition, by setting the route based on the measurement results collected based on the input criteria, it is possible to reduce the burden on the operator and select the optimum communication route even in a complicated communication network. .

  A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.

  [Supplementary Note 1] To select a signal path, input means for inputting a reference for selecting a signal path, and information obtained by measuring characteristics of a signal between transmission apparatuses or characteristics of a transmission path between the transmission apparatuses Monitoring means that collects measurement result information based on the above-mentioned criteria and measurement result information collected by the monitoring means and path setting means that sets a signal path according to a predetermined criterion set in advance A network management device characterized by the above.

  [Supplementary Note 2] The path setting means determines the priority of the transmission path based on the measurement result information collected by the monitoring means and a predetermined criterion set in advance, and sets the signal path based on the priority. The network management device according to Supplementary Note 1, wherein

  [Supplementary Note 3] Analyzing means for decomposing a criterion for selecting the path of the signal input from the input means into terms of a predetermined unit and determining a classification belonging to each term of the predetermined unit, The network management apparatus according to appendix 1 or 2, wherein the monitoring unit collects information corresponding to the terms classified by the analysis unit and uses the information as the measurement result information.

  [Supplementary Note 4] Any one of Supplementary notes 1 to 3, wherein the monitoring unit collects information based on a result of measuring a signal outside the band of a main signal in communication between the transmission apparatuses and obtains the measurement result information. The network management device described in 1.

  [Supplementary Note 5] The network management device according to any one of Supplementary notes 1 to 3, wherein the monitoring unit collects information based on a result of measuring an OSC signal between the transmission devices and uses the information as the measurement result information.

  [Appendix 6] It further comprises communication status determination means for determining whether or not communication of the main signal is performed between the transmission devices from which the monitoring means collects information, and the monitoring means communicates the main signal by the communication status determination means. If it is determined that the main signal has been communicated, the information obtained by measuring the main signal is collected as the measurement result information, and the communication status determining means determines that the main signal is not being communicated. The network management device according to any one of appendices 1 to 3, wherein information obtained by measuring an OSC signal is collected and used as the measurement result information.

  [Supplementary Note 7] A plurality of transmission apparatuses including a unit that measures characteristics of a transmission line or a signal transmitted / received on the transmission line, and a unit that transmits a measurement result of the measurement to another transmission apparatus. 7. The network management according to claim 1, wherein a predetermined transmission device of the transmission devices includes means for collecting the measurement results measured by each of the transmission devices, and the measurement results collected by the predetermined transmission device are A network management system, wherein the network management system is used as the measurement result information that is input to an apparatus and collected by the monitoring means.

  [Supplementary Note 8] A reference for selecting a signal path is input, and information on signal characteristics between transmission apparatuses or information on transmission path characteristics is collected based on the reference for selecting the signal path, and a measurement result. A communication path setting method, characterized in that a signal path is set based on the collected measurement result information and a predetermined reference set in advance as information.

  [Supplementary Note 9] The supplementary note 8, wherein a priority of a transmission path is determined based on the collected measurement result information and a predetermined criterion set in advance, and a signal path is set based on the priority. How to set up the communication path.

  [Supplementary Note 10] Information corresponding to the classified term is determined by decomposing a criterion for selecting the route of the input signal into terms of a predetermined unit, determining a classification belonging to each term of the predetermined unit. The communication path setting method according to appendix 8 or 9, wherein the measurement result information is collected.

  [Supplementary Note 11] The information according to any one of Supplementary Notes 8 to 10, wherein information based on a result of measuring a signal outside a main signal band in communication between the transmission apparatuses is collected and used as the measurement result information. Communication path setting method.

  [Supplementary note 12] The communication path setting method according to any one of Supplementary notes 8 to 10, wherein information based on a result of measuring an OSC signal between the transmission apparatuses is collected and used as the measurement result information.

  [Supplementary Note 13] It is determined whether communication of the main signal is performed between the transmission apparatuses that collect information. If it is determined that communication of the main signal is performed, information obtained by measuring the main signal is collected. If the main signal communication is determined not to be performed as the measurement result information, the information obtained by measuring the OSC signal is collected and used as the measurement result information. A method for setting a communication path as described above.

  The present invention relates to a technique for setting a communication path in a communication network, and can be used particularly for a network management system in an optical communication network using a wavelength division multiplexing system.

10 NMS server 11 Design concept receiver 12 Design concept DB
13 Design concept call / output display unit 14 Measurement data extraction instruction unit 15 Measurement data collection DB
Reference Signs List 16 Route index calculation unit 17 Prioritization unit 18 Route display unit 19 Manager unit 20 First transmission device 21 WXC unit 22 Optical amplifier for transmission 23 Optical amplifier for reception 24 Multiplexing unit 25 Separation unit 26 First transponder 27 Second Transponder 28 OSC unit 29 transmission signal measurement unit 30 reception signal measurement unit 31 Agent unit 40 second transmission device 41 WXC unit 42 optical amplifier for transmission 43 optical amplifier for reception 44 multiplexing unit 45 separation unit 46 first transponder 47 first 2 transponders 48 OSC unit 49 transmission signal measurement unit 50 reception signal measurement unit 60 third transmission device 61 first WXC unit 62 optical amplifier for transmission 63 optical amplifier for reception 64 multiplexing unit 65 separation unit 66 first transponder 67 Second transponder 68 First OSC unit 69 Transmission signal Measurement unit 70 Received signal measurement unit 71 Second WXC unit 72 Second OSC unit 80 Fourth transmission device 91 First transmission device 92 Second transmission device 93 Third transmission device 94 Fourth transmission device 100 NMS server 101 Design concept receiver 102 Design concept DB
103 Design Concept Calling / Output Display Unit 104 Measurement Data Extraction Instruction Unit 105 Measurement Data Collection DB
106 Route index calculation unit 107 Prioritization unit 108 Route display unit 109 Manager unit 111 Input unit 112 Monitoring unit 113 Route setting unit

Claims (10)

Input means for criteria for selecting the path of the signal is input,
Depending on the reference input to the input means, the monitoring means you collect as signal characteristics or measurement result information of information of characteristics of the measurement of the transmission path between the transmission device between the transmission device,
Based on the measurement result information collected by the monitoring means, an index calculating means for calculating an index for comparing signals transmitted through a plurality of signal paths;
Route setting means for determining a priority for each route based on the index calculated by the index calculation means, and adding the priority to the information indicating the route and outputting the information. Network management device. The path setting means calculates an index of a signal transmitted through the transmission path included in the path for each transmission path, and determines the priority for each path based on a result of adding the indexes. The network management device according to claim 1. Analysis means for decomposing a criterion for selecting a path of the signal input from the input means into terms of a predetermined unit and determining a classification belonging to each term of the predetermined unit;
The network management apparatus according to claim 1, wherein the monitoring unit collects information corresponding to the terms classified by the analysis unit and uses the information as the measurement result information.   The said monitoring means collects the information based on the result of having measured the signal outside the band of the main signal in communication between the said transmission apparatuses, and makes it the said measurement result information. Network management device. A communication status judging means for judging whether or not a communication of a main signal is performed between the transmission devices for collecting information by the monitoring means;
When it is determined that the communication of the main signal is performed by the communication status determination unit, the monitoring unit collects information obtained by measuring the main signal as the measurement result information,
4. The information according to any one of claims 1 to 3, wherein when the communication status determining means determines that communication of the main signal is not performed, information obtained by measuring an OSC signal is collected and used as the measurement result information. The network management device according to any one of the above. Means for measuring the characteristics of a transmission line or the characteristics of a signal transmitted and received on the transmission line;
A plurality of transmission devices comprising means for transmitting the measurement result by the measurement to another transmission device;
A network management device according to any one of claims 1 to 5,
The predetermined transmission device of the plurality of transmission devices further comprises means for collecting the measurement results measured by the transmission devices,
Network management system characterized in that the measurement result in which the predetermined transmission system is collected is used as the measurement result information the monitoring unit is entered collected in the network management device. Enter the criteria for selecting the signal path,
In accordance with the input standard, information on signal characteristics between transmission apparatuses or transmission path characteristics is collected as measurement result information ,
Based on the collected measurement result information , calculate an index for comparing signals transmitted through a plurality of signal paths,
A communication path setting method , comprising: determining a priority for each path based on the calculated index; adding the priority to information indicating the path and outputting the information. Disassembling a criterion for selecting a path of the input signal into terms of a predetermined unit, and determining a classification belonging to each term of the predetermined unit;
8. The communication path setting method according to claim 7, wherein information corresponding to the classified terms is collected and used as the measurement result information.   9. The communication path according to claim 7, wherein information based on a result of measuring a signal outside a main signal band in communication between the transmission apparatuses is collected and used as the measurement result information. Setting method. Determining whether communication of the main signal is performed between the transmission devices collecting information;
If it is determined that communication of the main signal is being performed, the information obtained by measuring the main signal is collected and used as the measurement result information.
9. The communication path according to claim 7, wherein when it is determined that communication of a main signal is not performed, information obtained by measuring an OSC signal is collected and used as the measurement result information. Setting method.

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