JP3925393B2 - Transmission capacity variable device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a transmission capacity variable device, and in particular, accommodates traffic in a link or path for each traffic flow, and further considers communication quality and accommodates traffic in a link or path as necessary. Alternatively, the present invention relates to a transmission capacity variable device for giving clear priority information to a path.
[0002]
[Prior art]
The amount of traffic input to and output from the network is increasing rapidly every year. For this reason, the communication apparatus which comprises a network cannot process traffic completely. As a result, the traffic is discarded and the destination is not easily reached. In recent years, such networks have been used for various purposes such as telephone, telemedicine, voice distribution, video distribution, mail, homepage, file exchange and the like. Therefore, in a network that accommodates traffic with high communication quality that must not be discarded or has a severe delay time limit, the following processing has been performed. When traffic with information for differentiating communication quality called main signal priority information is input to the communication device, the communication device identifies the main signal priority information of the traffic and uses the main signal priority information as necessary. Thus, priority control is performed for traffic discard control and output order control (for example, see Non-Patent Document 1, Non-Patent Document 2, and Non-Patent Document 3).
[0003]
As a communication apparatus that differentiates communication quality using the main signal priority information as described above, the apparatus is as shown in FIG. 36 or FIG. This communication device is composed of a signal transmission / reception unit 10, a path switching unit 40, a priority control device 20, and a transmission processing unit 30, or a signal transmission / reception unit 10, a path switching unit 40, a priority control device 20, a signal distribution unit 50, The transmission processing unit 30 is configured. The purpose of this communication device is to perform priority control on the main signal in frame units or packet units, and provide the main signal discard rate, the delay time required for transfer processing, and the main signal according to the main signal priority information. Priority control that differentiates the bandwidth to be used is realized.
[0004]
In recent years, a method for increasing the capacity by connecting a plurality of links or paths between opposing communication devices has been proposed in order to cope with the rapid increase in traffic volume in recent years.
[0005]
In summary, the transfer processing and transmission processing of the current communication device perform processing for exchanging the route of the input main signal for each destination and processing for performing priority control according to the main signal priority information, and are independent of the main signal priority information. The main signal is output to the link or path (for example, see Non-Patent Document 1, Non-Patent Document 2, and Non-Patent Document 3). That is, the link or path accommodates main signal groups having different communication qualities. Furthermore, the idea of giving priority information to such a link or path is shown in the GMPLS protocol proposed by standardization organizations such as IETF and ITU-T. One of the contents of the GMPLS protocol is to use this priority information to perform contention control regarding a plurality of paths sharing NW facilities such as bandwidth.
[0006]
[Non-Patent Document 1]
RFC 2474, §3.
[Non-Patent Document 2]
RFC2475, §2.
[Non-Patent Document 3]
RFC2597, §3, §4.
[0007]
[Problems to be solved by the invention]
However, in the above, the conventional communication apparatus characterized in that the main signal is accommodated in the link or path in the communication quality of the main signal has the following NW equipment oversupply problem and the main signal arrival order problem. .
[0008]
There are the following two NW equipment oversupply problems. The first problem is that if a main signal group that requires a backup system and a main signal group that does not require a backup system are accommodated in the same link or path, even a main signal that does not require a backup system can be obtained. The problem is that a spare system is provided. That is, the NW equipment is excessively supplied to the main signal group, and a lot of NW equipment must be prepared. The second problem is that when the main signal group accommodated in path A and the main signal group accommodated in path B share NW equipment as shown in FIG. If controlled, the main signal group δ having a low communication quality accommodated in the path B is not discarded, but the main signal group α having a high communication quality accommodated in the path A is discarded. . That is, the effect of contention control using link or path priority information is not sufficiently exhibited, and a main signal group with high communication quality is discarded. For this reason, it is not possible to use contention control using the priority information of the path or link, and it is necessary to prepare abundant NW facilities so that contention does not occur.
[0009]
Also, the main signal arrival order problem is that when the main signal group having the same data flow is divided, and the divided main signal group is assigned to a plurality of paths having different transmission paths and transmitted, the arrival order of the main signals is disturbed. The problem is that the upper layer that receives the group cannot restore the data.
[0010]
The present invention has been made in view of the above points, and an object of the present invention is to provide a transmission capacity variable device that can allocate a main signal to a link or a path using main signal priority information and a signal distribution rule. To do.
[0011]
[Means for Solving the Problems]
  The present invention is a transmission capacity variable device that assigns priority information to a link or path and performs link or path contention control based on the priority information,
  A signal transmitter / receiver for receiving the input main signal;
  A signal distribution unit that distributes the main signal by using main signal priority information for differentiating communication quality given to the main signal and a preset signal distribution rule;
  A signal distribution rule for distributing the main signal is set in advance, and a transmission processing unit that outputs the main signal allocated from the signal distribution unit to the link or path;
  A path exchanging unit for exchanging the main signal for each destination between the signal transmitting / receiving unit and the signal distributing unit or between the signal distributing unit and the transmission processing unit;
  With the transmission processorMultiple other variable transmission capacity connected to the variable transmission capacity deviceWithout connecting to the transmission processing unit between the deviceMultiple other transmission capacity variableapparatusConnect and relayPossible switch part,
  In order to set, delete, maintain, or change the state or attribute of a link or path, it has a signal distribution unit, a transmission processing unit, a path switching unit, and a device operation unit that controls a switch unit,
  The device operation unit
  The status of the transmission processing unit that is unused and in use, and the transmission processingPartThe status of the main signal priority information of the main signal input / output from / to, the setting status of the path switching unit, and the setting status of the signal distribution unit and the signal distribution rule are managed in the database as device status information, and according to changes in the device status Means for updating the database;
  Means for exchanging control information related to setting, deletion, maintenance of link or path, or change of state or attribute with other transmission capacity variable devices managed by each device operation unit When,
  Means for controlling to assign priority information to be given to a link or path according to main signal priority information of a main signal accommodated in each link or each path;
  Means for managing the priority information given to the link or path as status information in a database;
  When the main signal is input to the signal distribution unit and there is a shortage of links or paths that can accommodate the main signal, and there is an unused transmission processing unit in the apparatus, the signal distribution unit and the unused Dynamically establishing a connection relationship with the transmission processing unit, and allocating a main signal to the unused transmission processing unit;
  When the main signal is input to the signal distribution unit, when there is a shortage of links or paths that can accommodate the main signal, and there is no unused transmission processing unit in the device, a contention control rule set in advance The main signal priority information given to the main signal is compared with the priority information of each of all links connected to the apparatus or all paths one by one, and the setting of the link or path that matches the comparison result is deleted. A signal distribution unit, a transmission processing unit, a route exchange unit, and a switch unit for controlling the signal so as to accommodate the signal, and a means for setting a link or path.
[0012]
As a result, in a network adopting a point-to-point or multipoint-to-point connection form, it can be applied as a communication device constituting these networks. Also, the main signal can be output to a link or path suitable for each main signal priority information.
[0014]
  Also,Network topology applicable to variable capacity devices can be expanded to point-to-point, multipoint-to-point, point-to-multipoint, or multipoint-to-multipoint Become.
  Also, the facility information and the characteristics of the main signal input to the apparatus can be acquired from the apparatus operation unit mounted on the apparatus.
  In addition, when setting or deleting or maintaining a link or path, or changing a state attribute, each facility in the apparatus can be controlled from the apparatus operation unit in the apparatus.
  In addition, it is possible to acquire information about the equipment status of an arbitrary transmission capacity variable device and the characteristics of the main signal that inputs and outputs this device by using an arbitrary device operation unit.
  Also, from the device operation unit, control the equipment of the transmission capacity variable device with optional priority control through other device operation units, and set, delete, maintain, or change the status and attributes of the link or path Changes can be made.
  Further, it is possible to associate the contents of the priority information given to the link or path with the contents of the main signal priority information of the accommodated main signal.
  In addition, the priority information assigned to the link or path is stored in the database as status information, and the database is exchanged with other device operation units to obtain the priority information assigned to each link or path. Can be shared.
In addition, when the main signal is input to the signal distribution unit, if there are not enough links or paths that can accommodate the main signal, and there are unused transmission processing units in the device, signal distribution By dynamically establishing a connection relationship between a transmission section and an unused transmission processing section and assigning this main signal to this unused transmission processing section, it becomes possible to dynamically secure a transmission processing section. Equipment utilization efficiency is improved.
  In addition, it is possible to perform contention control related to sharing the NW equipment between the main signal and the link or path, and the NW equipment can be used effectively.
  In addition, since it is possible to omit the load of calculating the route to the destination, it is possible to omit the load of the relay processing of the main signal.
[0015]
The transmission capacity variable apparatus of the present invention further includes path management means for managing a path by using a plurality of paths connecting the same ground as one logical path.
[0016]
As a result, a plurality of paths connecting the same ground can be logically linked to the transmission capacity variable device and managed, so that the plurality of paths can be regarded as one path for operation management. This makes it possible to improve the line availability of this logical path.
[0019]
The transmission capacity variable apparatus of the present invention is trunked in order to treat a plurality of links connecting the same ground as one logical link or a plurality of paths connecting the same ground as one logical path. Having a trunking means.
[0020]
This makes it possible to operate and manage multiple links as one logical link or multiple paths as one logical path. Link line availability or path line availability Will improve.
[0043]
  The transmission capacity variable device of the present invention isThe device operation unit, together with the device operation unit of other transmission capacity variable devices,OutsideProvidedNetwork (NW) operation deviceByCentralized managementAndTheNW operation deviceBetweenExchange state information and control information related to link, path setting, deletion, maintenance, or state or attribute change.
[0044]
  As a result, it is possible to centrally manage a plurality of device operation units from the NW operation device, and through these device operation units, information on the equipment status of the variable transmission capacity device and the characteristics of the main signal input / output to / from the device is also provided. Can be acquired.It is also possible to set, delete, maintain, or change the state or attribute of a link or path.
[0050]
The apparatus operation unit of the variable transmission capacity apparatus according to the present invention allocates the main signal to the transmission processing unit according to the main signal priority information of each main signal when a plurality of main signals compete for the allocation of the main signal to the transmission processing unit. Means for controlling.
[0051]
As a result, when a plurality of main signals compete for the assignment of the main signal to the transmission processing unit, the device operation unit determines which main signal in the competing main signal group according to the main signal priority information of each main signal. By controlling whether to allocate the main signal to the transmission processing unit, it is possible to control the competition with respect to the competition that occurs with respect to the allocation of the main signal to the transmission processing unit, and to effectively use the NW equipment.
[0058]
The transmission capacity varying apparatus of the present invention includes an output traffic observation unit that observes the traffic amount between a signal distribution unit and a transmission processing unit, or between a signal transmission / reception unit and the signal distribution unit.
[0059]
As a result, it is possible to observe the characteristics of traffic that is input to the apparatus and output from the apparatus.
[0060]
The device operation unit of the transmission capacity variable device of the present invention can acquire the observation result from the output traffic observation unit, and compares the traffic data generated based on the acquired observation result with a preset threshold value. And means for changing the setting of the signal distribution rule of the signal distribution unit when the traffic data exceeds the threshold value.
[0061]
As a result, when the traffic data exceeds the threshold value, it is possible to change the setting of the signal distribution rule.
[0078]
The transmission capacity variable device of the present invention is used as a hierarchical network device in which a signal transmission / reception unit handles an upper layer and a transmission processing unit handles a lower layer signal. As a result, the priority information of the upper layer signal and the priority information of the lower layer signal are related, and the main signal having a high communication quality is handled as a main signal having a high communication quality in the lower layer. Can be handled as a main signal having a low communication quality even in a lower layer having a low communication quality.
[0079]
  The transmission capacity varying device of the present invention further includes a signal distribution rule for distributing the main signal in the signal distribution unit when main signal priority information is not given to the input / output main signal.
  The signal distribution rule of the variable transmission capacity device of the present invention treats a main signal group to which main signal priority information is not assigned as main signal priority information having the lowest priority.
[0080]
  Thereby, it is possible to process a main signal to which main signal priority information is not assigned.
  Also, processing can be performed for a main signal group to which main signal priority information is not assigned.
[0081]
The device operation unit of the transmission capacity variable device according to the present invention calculates the necessary number of links or paths necessary to accommodate the main signal based on the observation result, and adds the links or paths so as to satisfy the necessary number. Including means for controlling the signal distribution unit and the transmission processing unit for deletion;
[0082]
As a result, the link or path is dynamically added / deleted according to the traffic volume of the main signal group input / output to / from this apparatus, so that the NW equipment such as the link or path can be used effectively.
[0083]
The device operation unit of the variable transmission capacity apparatus of the present invention assigns priority information having high priority to a link or path that accommodates a main signal having main signal priority information having high priority, and the main signal having low priority. The link or path that accommodates the main signal having priority information includes means for giving priority information having a low priority.
[0084]
Thereby, it is possible to associate the high priority of the priority information given to the link or path with the high priority of the main signal priority information of the main signal to be accommodated.
[0085]
  The transmission capacity variable device of the present invention isWhen the path switching unit is between the signal transmitting / receiving unit and the signal distributing unit,Between signal transmitter / receiver and path switchIf not,An input traffic observation unit that observes traffic characteristics received by each signal transmission / reception unit is provided between the signal transmission / reception unit and the signal distribution unit.
[0086]
As a result, since the information observed by the output traffic monitoring unit is the traffic volume, main signal priority information, source address, or destination address, it is possible to grasp the traffic characteristics of the main signal group flowing through the signal distribution unit Thus, the setting of the signal distribution rule can be changed according to the traffic characteristics.
[0091]
The transmission capacity variable device of the present invention is an input traffic that observes traffic characteristics received by each signal transmitting / receiving unit between the signal transmitting / receiving unit and the path switching unit or between the signal transmitting / receiving unit and the signal distributing unit. An observation part is provided.
[0092]
Thereby, the input traffic characteristic received by the signal transmission / reception unit can be observed.
[0093]
The input traffic observation unit of the transmission capacity variable device of the present invention includes means for observing the traffic amount and main signal priority information received by each signal transmission / reception unit as traffic characteristics.
[0094]
As a result, the communication fee can be charged according to the traffic volume using the observation result of the input traffic observation unit.
[0095]
The signal distribution rule of the variable transmission capacity device of the present invention uses application information instead of main signal priority information.
[0096]
Thereby, the main signal group can be accommodated in the link or path for each application with respect to the main signal group to which the main signal priority information is not given.
[0097]
The signal distribution rule of the variable transmission capacity device of the present invention uses the information of the signal transmission / reception unit instead of the main signal priority information.
[0098]
Thereby, the main signal group can be accommodated in the link or path for each number of the signal transmitting / receiving unit with respect to the main signal group to which the main signal priority information is not given.
[0099]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0100]
[First Embodiment]
FIG. 1 shows a configuration of a transmission capacity variable device according to a first embodiment of the present invention. The apparatus 100 shown in the figure includes a plurality of signal transmission / reception units 110, a signal distribution unit 120, a plurality of transmission processing units 130, and a device operation unit 140.
[0101]
The signal transmission / reception unit 110 passes the main signal input to the apparatus 100 to the signal distribution unit 120.
[0102]
The signal distribution unit 120 distributes the main signal using the main signal priority information given to the main signal and a preset signal distribution rule, and allocates the main signal to the transmission processing unit 130.
[0103]
The transmission processing unit 130 outputs the main signal allocated from the signal distribution unit 120 to the link or path.
[0104]
The device operation unit 140 controls the signal distribution unit 120.
[0105]
Although FIG. 2 shows the transmission-side variable transmission capacity device 100, FIG. 4 shows the configuration (No. 1) of the reception-side transmission capacity variable device in the first embodiment of the present invention. On the reception side, the variable transmission capacity device 100 is configured by the signal transmission / reception unit 110, the transmission processing unit 130, and the device operation unit 140.
[0106]
FIG. 3 shows the configuration (part 2) of the transmission-side variable transmission capacity device according to the first embodiment of the present invention. The signal converging unit 170 shown in FIG. The main signal group is focused, and the focused main signal group is passed to the signal transmitting / receiving unit 110.
[0107]
The main signal input to this apparatus is received by the signal transmission / reception unit 110 and then passed to the signal distribution unit 120.
[0108]
The signal distribution unit 120 receives the main signal, and assigns it to the transmission processing unit 130 having a correspondence relationship with the main signal priority information given to the main signal according to the signal distribution rule. The signal distribution rule is set in the device operation unit 140 or the signal distribution unit 120, and determines the correspondence between the main signal priority information and the transmission processing unit 130.
[0109]
The main signal assigned to the transmission processing unit 130 is output to the link or path and transmitted to the priority control device type NW device on the opposite side.
[0110]
The device operation unit 140 controls the signal distribution unit 120 as necessary to change the signal distribution rule and the like.
[0111]
The main signal type handled by the signal distribution unit 120 includes an Ethernet (registered trademark) signal, an IPv4 packet, an IPv6 packet, a signal with a Shim header, an ATM cell signal, or the like.
[0112]
When the main signal priority information is not given to the main signal, a signal distribution rule for distributing the main signal input / output to / from the apparatus 100 in the signal distribution unit 120 is used. Alternatively, a main signal group to which main signal priority information is not assigned is handled as main signal priority information having the lowest priority. In this embodiment, the latter is not essential.
[0113]
In the signal distribution rule, application information can be used instead of the main signal priority information. FIG. 4 shows an example in which application information is used and main signal groups are accommodated in links or paths for each application. However, since the signal distribution unit 120 cannot perform signal distribution using application information, instead of signal distribution by the signal distribution unit 120 as shown in FIG. The signal distribution rule at this time defines the correspondence between the application information and the transmission processing unit 130. The application information is header information from layer 4 to layer 7 existing in the main signal, and is information that specifies which application processes the payload in the main signal. Thereby, a main signal to which main signal priority information is not given can be assigned to an appropriate transmission processing unit 130. However, in the present embodiment, a method of using application information instead of main signal priority information is not essential.
[0114]
Further, information of the signal transmission / reception unit 110 can be used instead of the main signal priority information. As shown in FIG. 6, the main signal can be accommodated in a link or path for each number of the signal transmitting / receiving unit 110 with respect to the main signal group to which the main signal priority information is not given. The signal distribution rule at this time defines the correspondence between the signal transmission / reception unit information and the transmission processing unit 130. The signal transmission / reception unit information is information for distinguishing the signal transmission / reception unit 110 from other signal transmission / reception units installed in the same transmission capacity variable device, and examples include an interface number and a port number. Thereby, a main signal to which main signal priority information is not assigned can be assigned to an appropriate transmission processing unit 130. However, in the present embodiment, it is not essential to use the signal transmitting / receiving unit information instead of the main signal priority information.
[0115]
When a main signal is output to a separate link or path for each main signal priority, main signals having the same communication quality can be accommodated in a certain link or path. For this reason, link level or path level services such as protection and restoration can be provided to all main signals accommodated in a certain link or path without excess or deficiency.
[0116]
When updating the above signal distribution rule, as shown in FIG. 7, in addition to the configuration shown in FIG. 1, output traffic observation for observing traffic between the signal distribution unit 120 and the transmission processing unit 130 8 or in addition to the configuration shown in FIG. 1, a traffic observation unit 170 is provided between the signal transmission / reception unit 110 and the signal distribution unit 120 to output from the apparatus 100 as shown in FIG. Observe traffic characteristics and update signal distribution rules based on observation results. The output traffic observation unit 170 observes at least one of the traffic volume, main signal priority information, transmission source address, or destination address, and outputs this as traffic characteristics. As a result, the device operation unit 140 obtains traffic characteristics from the output traffic observation unit 170, generates traffic data, and compares the signal with a predetermined threshold value. When the traffic data exceeds the predetermined threshold value, the signal distribution is performed. Set and change rules.
[0117]
In addition, when charging a communication line user directly connected to the apparatus 100 on a pay-as-you-go basis, an input traffic observation unit 190 is provided between the signal transmission / reception unit 110 and the signal distribution unit 120 as shown in FIG. Is provided. The input traffic observation unit 190 observes the amount of traffic from the output of the signal transmission / reception unit 110 and how much traffic the communication line user has transmitted to the network for each main signal priority information. Based on this result, the communication line provider can charge a communication fee to the communication line user. In the present embodiment, it is not essential to provide the input traffic observation unit 190.
[0118]
As described above, since it is not necessary to provide an excessive service for the main signal, it is not necessary to prepare a useless NW facility. In addition, since the main signal is accommodated in the link or path for each flow, the arrival order of the main signal is naturally controlled, and the apparatus 100 may not have the order control function. That is, since the NW equipment cost can be kept low, the communication fee can be set reasonably.
[0119]
However, this embodiment can be handled only for a uniform main signal group of destinations. That is, the network topology to which the apparatus 100 can be applied is point-to-point or multipoint-to-point.
[0120]
[Second Embodiment]
FIG. 10 shows the configuration of the transmission capacity variable device in the second exemplary embodiment of the present invention. The configuration in the present embodiment is different from that of the apparatus 100 in the first embodiment described above between the signal transmission / reception unit 110 and the signal distribution unit 120 or between the signal distribution unit 120 and the transmission processing unit 130. In addition, a path exchange unit 150 is provided.
[0121]
The route exchange unit 150 has a function of exchanging routes so that the main signal group input to the route exchange unit 150 reaches the destination. In the present embodiment, the device operation unit 140 has a function of controlling the route exchange unit 150.
[0122]
FIG. 11 shows the configuration (part 1) of the transmission-side variable transmission capacity device according to the second embodiment of the present invention. In the transmission-side device 100, the signal transmission / reception unit 110 and the signal distribution unit 120 are A route exchanging unit 150 is provided. The device operation unit 140 controls the path exchange unit 150 and the signal distribution unit 120.
[0123]
FIG. 12 shows the configuration (No. 1) of the transmission capacity variable device on the receiving side according to the second embodiment of the present invention. The configuration in the figure shows a configuration when the transmission side apparatus adopts the configuration in FIG. 11, and a path switching unit 150 is provided between the signal transmitting / receiving unit 110 and the transmission processing unit 130, and the reception The device operation unit 140 of the device 100 on the side controls only the route exchange unit 150.
[0124]
FIG. 13 shows the configuration (part 2) of the transmission-side variable transmission capacity device according to the second embodiment of the present invention. In the transmission-side device, between the signal distribution unit 120 and the transmission processing unit 130, FIG. A path exchanging unit 150 is provided, and the device operation unit 140 of the transmission-side apparatus 100 controls only the path exchanging unit 150.
[0125]
FIG. 14 shows the configuration (No. 2) of the transmission capacity variable device on the receiving side in the second embodiment of the present invention. The configuration in the figure shows a configuration when the transmission side apparatus adopts the configuration in FIG. 12, and a path switching unit 150 is provided between the signal transmitting / receiving unit 110 and the transmission processing unit 130. In the receiving apparatus 100, the apparatus operation unit 140 controls only the path exchange unit 150.
[0126]
The route switching unit 150 distributes the Ethernet (registered trademark) main signal input to the apparatus 100 according to the destination. The distributed Ethernet (registered trademark) main signal is allocated to the signal distribution unit 120. The allocation method follows the signal distribution rule that defines the correspondence between the main signal priority information described in the VLAN tag of the Ethernet (registered trademark) main signal and the transmission processing unit 130. It is assigned to a certain transmission processing unit 130.
[0127]
When the main signal priority information is not given to the main signal, a signal distribution rule for distributing the main signal input / output to / from the apparatus 100 in the signal distribution unit 120 is used. Alternatively, a main signal group to which main signal priority information is not assigned is handled as main signal priority information having the lowest priority. In this embodiment, the latter is not essential.
[0128]
In the signal distribution rule, application information can be used instead of the main signal priority information. The signal distribution rule at this time defines the correspondence between the application information and the transmission processing unit 130. The application information is header information from layer 4 to layer 7 existing in the main signal, and is information that specifies which application processes the payload in the main signal. Thereby, a main signal to which main signal priority information is not given can be assigned to an appropriate transmission processing unit 130. However, in the present embodiment, a method of using application information instead of main signal priority information is not essential.
[0129]
In addition, signal transmission / reception unit information can be used instead of the main signal priority information. The signal distribution rule at this time defines the correspondence between the signal transmission / reception unit information and the transmission processing unit 130. The signal transmission / reception unit information is information for distinguishing the signal transmission / reception unit 110 from other signal transmission / reception units installed in the same transmission capacity variable device, and examples include an interface number and a port number. Thereby, a main signal to which main signal priority information is not assigned can be assigned to an appropriate transmission processing unit 130. However, in the present embodiment, it is not essential to use the signal transmitting / receiving unit information instead of the main signal priority information.
[0130]
The transmission processing unit 130 outputs the Ethernet (registered trademark) main signal to the Ethernet (registered trademark) link.
[0131]
A plurality of Ethernet (registered trademark) links connecting the same ground are handled as one large-capacity Ethernet (registered trademark) link. Link Aggregation technology is used as a means for bundling a plurality of Ethernet (registered trademark) links.
[0132]
As shown in FIG. 15, the device operation unit 140 collects status information from the path switching unit 150, the signal distribution unit 120, and the transmission processing unit 130, manages the status information related to the device equipment as a database, The status can be retrieved and referenced.
[0133]
Further, as shown in FIG. 16, the device operation unit 140 sets, deletes, maintains, or changes the state or attribute of the link or path, so that the signal distribution unit 120, the path switching unit 160, and the transmission processing unit 130 Exchange control signals between them. Thereby, it is possible to change the rule of signal distribution and the setting of equipment. That is, it is possible to control the equipment from the equipment operation unit 140.
[0134]
Further, as shown in FIG. 17, the apparatus operation unit 140 exchanges a database managed by each apparatus operation unit 140 with another apparatus operation unit, and the equipment of the other apparatus from the apparatus operation unit 140. The status can be retrieved and referenced.
[0135]
Furthermore, as shown in FIG. 18, the device operation unit 140 exchanges control information related to link or path setting, deletion, maintenance, or change of state or attribute with another device operation unit. It is possible to transmit control information from the device operation unit 140 to the device operation unit of another device and change the equipment setting of the other device. Note that the exchange of the database and the exchange of control information are not essential in the present embodiment.
[0136]
Further, instead of using the above database, as shown in FIGS. 19 and 20, an NW operation device 200 is prepared outside the device, and the NW operation device 200 centrally manages a plurality of device operation units 140. It is possible to search and refer to the equipment state of the apparatus under management from the NW operation apparatus 200.
[0137]
Further, instead of exchanging the control information, the NW operation device 200 is used to transmit control information from the NW operation device 200 to the managed device operation unit 140, and the equipment of the managed device The setting can be changed. In the present embodiment, it is not essential to use the NW operation device 200.
[0138]
As described above, by operating the apparatus 100, the main signal input to the apparatus 100 can be allocated to the transmission processing unit 130 having a correspondence relationship with the main signal priority information. For this reason, even if a link level service such as protection is provided, an excessive service is not provided for each main signal, and as a result, it is not necessary to prepare a wasteful NW facility.
[0139]
In addition, since the main signal is accommodated in the link or path for each flow, the arrival order of the main signal is naturally controlled, and the apparatus 100 may not have the order control function.
[0140]
It is also possible to handle signals with a Shim header. As the handling of the signal with Shim header, the signal distribution unit 120 handles the signal with Shim header, and the signal distribution rule uses the main signal priority information described in the EXP field in the Shim header, or the label For example, the label information described in the field is used, or the main signal priority information and the label information are used in combination.
[0141]
As described above, by operating the apparatus 100, it is possible to allocate the main signal input to the apparatus 100 to the transmission processing unit 130 having a correspondence relationship with the main signal priority information. For this reason, even if a link level service such as protection is provided, an excessive service is not provided for each main signal, and as a result, it is not necessary to prepare useless NW facilities.
[0142]
Further, since the main signal is accommodated in the link or path for each flow, the arrival order of the main signal is naturally controlled, and the apparatus 100 may not have the order control function.
[0143]
[Third Embodiment]
FIG. 21 shows the configuration (part 1) of the variable transmission capacity device according to the third embodiment of the present invention. The transmission capacity variable apparatus 100 shown in the figure has a network hierarchical apparatus configuration, and includes a signal transmission / reception unit 110, a signal distribution unit 120, a transmission processing unit 130, a device control unit 140, and a switch unit 160.
[0144]
The upper layer main signal input to the apparatus 100 is received by the signal transmission / reception unit 110 and then passed to the signal division unit 120.
[0145]
The upper layer main signal input to the signal dividing unit 120 is assigned to the transmission processing unit 130 having a correspondence relationship with the main signal priority information of the upper layer main signal according to the signal distribution rule. The signal distribution rule is set in the apparatus operation unit 140 or the signal distribution unit 120 and determines the correspondence between the main signal priority information and the transmission processing unit 130.
[0146]
The upper layer main signal allocated to the transmission processing unit 130 is mapped to the lower layer signal format, and the lower layer main signal is output to the link or path.
[0147]
  The link or path is route-converted by the switch unit 160 in order to connect to the destination priority control type NW device. The link or path is transmitted by the relay device by the function of the switch unit 160.PartTransmission processing of the destination device without connecting toPartCan be connected. For this reason, the relay apparatus does not need to process the lower layer main signal by the transmission processing unit and the path switching unit, and the load on the relay apparatus is reduced.
[0148]
The device operation unit 140 controls the signal distribution unit 120 as necessary to change the signal distribution rule and the like.
[0149]
FIG. 22 shows the configuration (part 2) of the variable transmission capacity device according to the third embodiment of the present invention. The configuration shown in the figure is a configuration obtained by adding a route switching unit 150 to the configuration of FIG. As a result, the apparatus 100 can handle various main signal groups of destinations. That is, the network topology to which the apparatus 100 can be applied is point-to-point, multipoint-to-point, or multipoint-to-multipoint. However, in the present embodiment, it is not essential to use the route exchange unit 150.
[0150]
The device operation unit 140 manages state information related to device equipment as a database, and can search and refer to the state of device equipment. Furthermore, the device operation unit 140 can change the signal distribution rule and change the setting of the equipment. That is, it is possible to control the equipment from the equipment operation unit 140.
[0151]
In addition, the database managed by the device operation unit 140 can be exchanged, and the database is exchanged between the device operation unit 140 and another device operation unit. It becomes possible to search and refer to the equipment state. Note that exchanging databases is not essential in the present embodiment.
[0152]
Furthermore, by exchanging control information related to link, path setting, deletion, maintenance, or change of state or attribute, the control information is transmitted from the device operation unit 140 to another device operation unit. It is also possible to change the equipment setting. Thereby, the trouble of apparatus operation is reduced. Note that the exchange of control information is not essential in the present embodiment.
[0153]
Further, an NW operation device is provided outside the present device 100 as shown in FIGS. 19 and 20 described above, and a plurality of device operation units 140 are centrally managed by the NW operation device 200 and are managed by the NW operation device 200. It is possible to search and refer to the equipment state of
[0154]
Further, instead of the device operation unit 140 exchanging control information regarding setting or deleting or maintaining a link or path with another device operation unit, or changing the state or attribute, from the NW operation device 200 It is also possible to transmit control information to the managed device operation unit 140 and change the equipment setting of the managed device. Thereby, the trouble of apparatus operation is reduced. However, the use of the NW operation device is not essential in the present embodiment.
[0155]
An Ethernet (registered trademark) link or a fiber channel link is used as a link for accommodating the lower layer main signal output from the transmission processing unit 130. In addition, as a path for accommodating the lower layer main signal output from the transmission processing unit 130, an STS / VC path, a VP / VC path, an LSP, a SONET / SDH path, a wireless path, or an OCh / OTU / ODU path is used. To do.
[0156]
The combination relationship between the type of the upper layer main signal and the type of the lower layer main signal may be any combination as long as the layers of the upper layer main signal and the lower layer main signal are different.
[0157]
Further, as shown in FIG. 23, a plurality of paths connecting the same ground are managed as one logical path. In particular, when a SONET / SDH path or an OCh / OTU / ODU path is used as a path for accommodating a lower layer main signal, it can be managed using a bar channel concatenation technique. By managing a plurality of paths connecting the same ground as one logical path, it is possible to reduce the trouble of maintaining and operating this logical path. However, in the present embodiment, it is not essential to use a technique for managing a plurality of paths as one logical path or a virtual concatenation technique.
[0158]
Further, as shown in FIG. 24, a plurality of links or paths connecting the same ground are trunked as one logical link or logical path. In particular, when an Ethernet (registered trademark) link is used as a link, a Link Aggregation technique can be used as a trunking technique. In particular, when a SONET / SDH path is used as a path, an RPR technique can be used as a trunking technique. By trunking a plurality of links connecting the same ground as one logical link, the operation time of the logical link can be improved, and the transmission capacity between the grounds can be increased. However, in this embodiment, it is indispensable to use a plurality of links connecting the same ground, a method of trunking as a single logical link or logical path, a link aggregation technology, or an RPR technology. is not.
[0159]
Hereinafter, an OCh / OTU / ODU path will be described as a path accommodating the lower layer main signal. However, the same effect can be obtained even when other types of links and paths are used. An Ethernet (registered trademark) signal will be described as an upper layer main signal handled by the signal distribution unit 120. However, the same effect can be obtained even when other types of signals are used.
[0160]
FIG. 25 is a diagram for explaining assignment of priority information to be given to a link path or a path in the third embodiment of the present invention.
[0161]
Priority information can be assigned to each OCh / OTU / ODU path, and the device operation unit 140 can manage the priority information of the OCh / OTU / ODU path. As a result, when the OCh / OTU / ODU path competes with other OCh / OTU / ODU paths and shares NW facilities (available transmission bandwidth, etc.), the priority information assigned to each path is used. Contention can be controlled.
[0162]
In addition, as a method of assigning priority to the OCh / OTU / ODU path, high priority information is given to a link or a path that accommodates a main signal having main signal priority information with high priority. A link or path that accommodates a main signal having main signal priority information with a low priority is assigned priority information with a low priority so that the priority information of the OCh / OTU / ODU path can be accommodated in this path. The main signal priority information of the Ethernet (registered trademark) main signal can be related. As a result, when multiple OCh / OTU / ODU paths compete with each other for sharing NW equipment, priority is given by assigning NW equipment to the OCh / OTU / ODU path having the highest priority information. NW equipment can be assigned to the main signal having the highest degree.
[0163]
When the OCh / OTU / ODU path to which the Ethernet (registered trademark) main signal input to the signal distribution unit 120 is allocated is insufficient, and when there are no unused transmission processing units 130 in the apparatus 100 In accordance with the contention control rule set by the device operation unit 140, the main signal priority information of the Ethernet (registered trademark) main signal is compared with the priority information of the Ethernet (registered trademark) as shown in FIG. The OCh / OTU / ODU path can be set to delete the OCh / OTU / ODU path and accommodate this Ethernet (registered trademark) main signal.
[0164]
At this time, the device operation unit 140 can dynamically establish a connection relationship between the signal distribution unit 120 and the transmission processing unit 130. An image of this operation is shown in FIG.
[0165]
In addition, when the OCh / OTU / ODU path for allocating the Ethernet (registered trademark) main signal input to the signal distribution unit 120 is insufficient, and there is no unused transmission processing unit 130 in the apparatus 100 When the device operation unit 140 cannot dynamically establish the connection relationship between the signal distribution unit 120 and the transmission processing unit 130, as shown in FIG. 28, the device operation unit 140 is set according to the contention control rule set. The main signal priority information given to the main signal and the priority information of all the links connected to the signal distribution unit 120 or all the paths are compared one by one, and the comparison result is the link or path matching the competition control rule. The signal distribution unit 120, the transmission processing unit 130, and the path switching unit 150 are controlled so that the setting is deleted and the main signal is accommodated. Ku is the setting of the path.
[0166]
When this is applied to the OCh / OTU / ODU path, the device operation unit 140 follows a competition rule set in itself, and the priority lower than the priority is compared with the main signal priority information of the Ethernet (registered trademark) main signal. The OCh / OTU / ODU path having the information can be deleted and the OCh / OTU / ODU path can be set so as to accommodate this Ethernet (registered trademark) main signal. An image of this operation is shown in FIG.
[0167]
In the operation shown in FIG. 28 and the operation shown in FIG. 29, the operation shown in FIG. 29 is less effective than FIG. 28 from the viewpoint of effective use of the NW equipment, but the operation shown in FIG. Compared with the operation | movement shown, the function of the apparatus operation part 140 can be restrained low, and the cost reduction of the apparatus operation part 140 can be achieved.
[0168]
In the present embodiment, priority information to be assigned to the link or path is assigned according to the main signal priority information of the main signal accommodated in the link or path, and the device operation unit 140 is assigned to the link or path. The priority information assigned to the main signal is compared in accordance with the contention control rule set by the device operation unit 140, and the link or path setting that matches the comparison result is set. Delete and set the link or path by controlling the signal signal distribution unit 120, the transmission processing unit 130, and the path switching unit 150 so as to accommodate the main signal, and has high priority main signal priority information High priority for the link or path containing the main signal Grant broadcast, it is a link or path to accommodate a main signal having a low main signal priority information priority to impart low priority priority information is not essential.
[0169]
Next, a case where traffic observation is performed will be described.
[0170]
FIG. 30 shows a configuration of a transmission capacity variable device provided with an output traffic observation unit in the third embodiment of the present invention. The variable transmission capacity device 100 shown in the figure has a configuration in which an output traffic observation unit 180 is provided between the signal distribution unit 120 and the transmission processing unit 130.
[0171]
The output traffic observation unit 180 observes the traffic volume of the Ethernet (registered trademark) main signal output from the signal distribution unit 120 to the transmission processing unit 130, and the device operation unit 140 determines the signal distribution unit 120 according to the observation result. In addition, the setting of the transmission processing unit 130 and the setting of the NW facility of another device can be changed, and the number of OCh / OTU / ODU paths accommodating this Ethernet (registered trademark) main signal can be dynamically changed. As a result, the lower layer band for accommodating the upper layer main signal can be dynamically changed according to the traffic amount of the upper layer main signal, and the unnecessary lower layer band can be changed by using this variable function. The lower layer bandwidth can be dynamically provided in response to the demand for increasing the lower layer bandwidth.
[0172]
In FIG. 30, the Ethernet (registered trademark) main signal allocated from the signal distribution unit 120 to the transmission processing unit 130 is observed by the output traffic observation unit 180, and the observed traffic volume information, main signal priority information, destination address information, transmission The original address information and the like are notified to the device operation unit 140. The device operation unit 140 compares the threshold value set for itself with the notified traffic amount information, and determines whether to add or delete the OCh / OTU / ODU path according to the comparison result, or to do nothing. Make a decision.
[0173]
When an OCh / OTU / ODU path is added or deleted, the device operation unit 140 also determines how many OCh / OTU / ODU paths are added or how many are deleted. Based on the above determination result, the device operation unit 140 restricts the signal distribution unit 120, the transmission processing unit 130, and the NW facilities of other devices in the device, and opens / deletes the OCh / OTU / ODU path. To do.
[0174]
An example of adding an OCh / OTU / ODU path is shown in FIG. An Ethernet (registered trademark) main signal having main signal priority information “7” is allocated to the transmission processing unit 130A. Since the traffic volume of the Ethernet (registered trademark) main signal with the main signal priority information “7” has increased, the device operation unit 140 converts the Ethernet (registered trademark) main signal with the main signal priority information “7” into two OCh / OTUs. The transmission processing unit 130, the signal distribution unit 120, and other equipment in the device are controlled so as to be accommodated in the / ODU path. At this time, the device operation unit 140 also changes the signal distribution rule. The signal distribution rule before adding the OCh / OTU / ODU path is to allocate the Ethernet (registered trademark) main signal to the transmission processing unit 130A using the information of the main signal priority information “7”. According to this signal distribution rule, the Ethernet (registered trademark) main signal having the main signal priority information “7” cannot be allocated with load distribution to the transmission processing unit 130A and the transmission processing unit 130B. In order to distribute and allocate the Ethernet (registered trademark) main signal of the main priority information “7” to the transmission processing unit 130A and the transmission processing unit 130B, the signal distribution rule is the main signal priority information “7” and the destination MAC An Ethernet (registered trademark) main signal whose bit value of the last digit of the address is “0” is allocated to the transmission processing unit 130A, the main signal priority information “7”, and the bit of the last digit of the MAC address is “7”. The Ethernet (registered trademark) main signal, which is 1 ″, is changed to be assigned to the transmission processing unit 130B.
[0175]
As described above, by changing various settings, the Ethernet (registered trademark) main signal of the main signal priority information “7” is converted into the OCh / OTU / ODU path according to the traffic amount of the Ethernet (registered trademark) main signal. Can be accommodated by distributing the load to two OCh / OTU / ODU paths. An image of this operation is shown in FIG. In the figure, the main signal priority information given to the main signal input to the signal distribution unit 120 is the same, but the destination address information is different.
[0176]
When deleting the OCh / OTU / ODU path, the transmission operation unit 130 and the signal distribution unit 120 in the apparatus 100 are deleted so that the apparatus operation unit 140 deletes the OCh / OTU / ODU path in the same manner as the expansion operation. Control NW equipment of other devices. Since the lower layer bandwidth can be varied according to the traffic amount of the upper layer main signal, the NW equipment can be used effectively.
[0177]
The path connecting the apparatus 100 and the opposite apparatus may be either symmetric or asymmetric with respect to the upstream path capacity and the downstream path capacity. Furthermore, for a plurality of paths connecting between the apparatus 100 and the opposite apparatus, when these paths are all set to the same path, each path is set to a path different from the other paths. In some cases, there are route setting methods for two paths.
[0178]
Further, when a plurality of main signals compete with respect to assigning the main signal to the transmission processing unit 130, the apparatus operation unit 140 performs contention control using the main signal priority information as shown in FIG. The main signal having the highest communication quality is preferentially assigned to the transmission processing unit.
[0179]
Further, when there are not enough links for allocating the main signal input to the signal distribution unit 120 and there are remaining unused transmission processing units 130 in the apparatus 100, as shown in FIG. The connection relationship between the signal distribution unit 120 and the unused transmission processing unit 130 is dynamically established, and the main signal is assigned to the unused transmission processing unit 130.
[0180]
Note that the assignment to the transmission processing unit 130 is not essential in the present embodiment. Further, the traffic amount observation process is not essential in the present embodiment.
[0181]
Finally, the accounting process will be described.
[0182]
When charging a communication line user directly connected to the apparatus 100 on a pay-as-you-go basis, an input traffic observation unit 190 is provided between the signal distribution unit 120 and the transmission processing unit 130 as shown in FIG.
[0183]
The input traffic observation unit 190 observes how much traffic the communication line user has transmitted to the network for each main signal priority information. Depending on the observation result, the communication line provider can charge a communication fee to the communication line user. In the present embodiment, it is not essential to provide the input traffic observation unit 180.
[0184]
It is possible to construct the configuration of the transmission capacity variable device as a program and install it in a computer used as the transmission capacity variable device.
[0185]
The constructed program is stored in a hard disk device connected to a computer used as a variable transmission capacity device, a portable storage medium such as a flexible disk or a CD-ROM, and the computer is used when carrying out the present invention. It is also possible to install it.
[0186]
The present invention is not limited to the above-described embodiment, and various modifications and applications can be made within the scope of the claims.
[0187]
【The invention's effect】
As described above, according to the transmission capacity variable device of the present invention, the following five effects can be obtained.
[0188]
(1) Since no excessive NW equipment is provided for the main signal, the investment cost for the NW equipment can be reduced as a result.
[0189]
(2) Even when the main signal group is divided and transmitted using a plurality of links and paths, it is not necessary to control the order of the main signal group in the destination apparatus, and the apparatus configuration is simplified. By simplifying the device configuration, the device cost is reduced.
[0190]
(3) The NW equipment that has been secured in excess can be dynamically opened, and the NW equipment can be applied dynamically as needed, so that the NW equipment can be used effectively. Since the NW facilities can be used effectively, an increase in the number of NW facilities can be suppressed, and the investment cost to the NW facilities can be reduced.
[0191]
(4) When a plurality of main signal groups share an NW facility, it is possible to provide the NW facility for the main signal group having a high priority by controlling the competition using priority information given to the link or path. . For this reason, NW equipment can be used more effectively and the investment cost to NW equipment can be reduced.
[0192]
(5) The communication line provider can charge the communication line user for a communication line usage fee according to the characteristics of the signal transmitted by the communication line user. A reasonable price can be set.
[0193]
Due to the above effect, the NW equipment cost can be greatly reduced, and as a reflection, the communication line user can use the communication line at a low price.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a transmission capacity variable device according to a first embodiment of the present invention.
FIG. 2 is a configuration diagram (No. 1) of a transmission capacity variable device on the reception side according to the first embodiment of the present invention;
FIG. 3 is a configuration diagram (No. 2) of the transmission capacity variable device on the reception side according to the first embodiment of the present invention;
FIG. 4 is an example (part 1) of using application information according to the first embodiment of the present invention.
FIG. 5 is an example (part 2) of using application information according to the first embodiment of the present invention.
FIG. 6 is a diagram for explaining processing when main signal priority information is not assigned to a main signal group in the first embodiment of the present invention;
FIG. 7 is a configuration diagram (No. 1) of a transmission capacity variable device to which an output traffic observation unit is added according to the first embodiment of the present invention;
FIG. 8 is a configuration diagram (No. 2) of the transmission capacity variable device to which the output traffic observation unit is added according to the first embodiment of the present invention.
FIG. 9 is a configuration diagram of a transmission capacity variable device provided with an input traffic observation unit according to the first embodiment of the present invention.
FIG. 10 is a configuration diagram of a transmission capacity variable device according to a second embodiment of the present invention.
FIG. 11 is a configuration diagram (No. 1) of a transmission-side variable transmission capacity device according to a second embodiment of the present invention.
FIG. 12 is a configuration diagram (No. 1) of a transmission-side variable transmission capacity device in a second embodiment of the present invention;
FIG. 13 is a configuration diagram (No. 2) of the transmission-side transmission capacity variable device in the second embodiment of the present invention;
FIG. 14 is a configuration diagram (No. 2) of the transmission-side variable transmission capacity device in the second embodiment of the present invention;
FIG. 15 is a diagram for explaining state information collection processing according to the second embodiment of the present invention;
FIG. 16 is a diagram for explaining exchange of control signals in the second embodiment of the present invention.
FIG. 17 is an example of database exchange in the second embodiment of the present invention;
FIG. 18 is an example of control information exchange in the second embodiment of the present invention;
FIG. 19 is an example (part 1) of using the NW operation device according to the second embodiment of the present invention;
FIG. 20 is an example (part 2) of using the NW operation device according to the second embodiment of the present invention;
FIG. 21 is a configuration diagram (No. 1) of a transmission capacity variable device according to a third embodiment of the present invention;
FIG. 22 is a configuration diagram (No. 2) of the transmission capacity variable device according to the third embodiment of the present invention;
FIG. 23 is a diagram for explaining logical path management according to the third embodiment of this invention;
FIG. 24 is a diagram for explaining trunking in the third embodiment of the present invention;
FIG. 25 is a diagram for explaining assignment of priority information to be assigned to a link or a path in the third embodiment of the present invention.
FIG. 26 is a diagram (No. 1) for explaining processing using a conflict control rule in the third embodiment of the present invention;
FIG. 27 is a diagram (No. 1) for explaining an operation of setting an OCh / OTU / ODU path according to the third embodiment of the invention;
FIG. 28 is a diagram (No. 2) for explaining the process using the conflict control rule in the third embodiment of the present invention;
FIG. 29 is a diagram (No. 2) for explaining the operation of setting the OCh / OTU / ODU path in the third embodiment of the invention;
FIG. 30 is a configuration diagram of a transmission capacity variable device including an output traffic observation unit according to the third embodiment of the present invention.
FIG. 31 is an example of adding an OCh / OTU / ODU path in the third embodiment of the present invention;
FIG. 32 is a diagram for explaining distributed accommodation of paths in the third embodiment of the present invention;
FIG. 33 is a diagram for explaining competition control according to the third embodiment of the present invention.
FIG. 34 is a diagram for explaining allocation to unused transmission processing according to the third embodiment of the present invention;
FIG. 35 is a configuration diagram of a transmission capacity variable device having a traffic observation unit according to a third embodiment of the present invention.
FIG. 36 is a diagram of a conventional apparatus configuration (part 1).
FIG. 37 is a configuration diagram of a conventional apparatus (part 2);
FIG. 38 is a diagram for explaining a conventional problem.
[Explanation of symbols]
100 Transmission capacity variable device
110 Signal transceiver
120 Signal distributor
130 Transmission processing unit
140 Device operation unit
150 Route switching part
160 Switch part
170 Signal focusing unit
180 Output traffic observation section
190 Input traffic observation section
200 NW (network) operation device

Claims (15)

A transmission capacity variable device that assigns priority information to a link or path and performs link or path contention control based on the priority information,
A signal transmitter / receiver for receiving the input main signal;
A signal distribution unit that distributes the main signal by using main signal priority information for differentiating communication quality given to the main signal, and a preset signal distribution rule;
A signal distribution rule for distributing a main signal is set in advance, and a transmission processing unit that outputs the main signal allocated from the signal distribution unit to a link or a path;
A path exchanging unit for exchanging a main signal for each destination between the signal transmitting / receiving unit and the signal distributing unit or between the signal distributing unit and the transmission processing unit;
Between the transmission processing unit and a plurality of other transmission capacity variable devices connected to the transmission capacity variable device, without connecting the transmission processing unit , the plurality of other transmission capacity variable devices , A switch part capable of relaying ;
An apparatus operation unit for controlling the signal distribution unit, the transmission processing unit, the path switching unit, and the switch unit to set, delete, maintain, or change a state or attribute of a link or path; ,
The device operation unit is
For the self-device, the unused and the transmission processing unit in usage status of the main signal priority information of the main signal to be output from said transmission processing unit, setting status of the route exchange unit, and said signal distributor and signal distribution Means for managing rule setting status in the database as device status information, and updating the database in response to changes in device status;
Exchanges information on the database managed by each device operation unit and control information on link or path setting, deletion, maintenance, or change of status and attributes with other variable transmission capacity devices Means,
Means for controlling to assign priority information to be given to a link or path according to main signal priority information of a main signal accommodated in each link or each path;
Means for managing the priority information given to the link or path in the database as status information;
When a main signal is input to the signal distribution unit, when there is a shortage of links or paths that can accommodate the main signal and there is an unused transmission processing unit in the apparatus, the signal distribution unit and the Means for dynamically establishing a connection relationship with a used transmission processing unit and allocating a main signal to the unused transmission processing unit;
When the main signal is input to the signal distribution unit, there is a shortage of links or paths that can accommodate the main signal, and there is no unused transmission processing unit in the apparatus, a contention control that is set in advance According to the rule, the main signal priority information given to the main signal and the priority information of all the links connected to the device or all the paths are compared one by one, the setting of the link or path matching the comparison result is deleted, and the And a means for controlling the signal distribution unit, the transmission processing unit, the route switching unit, and the switch unit to set a link or a path so as to accommodate a main signal. 2. The variable transmission capacity device according to claim 1, further comprising path management means for managing a plurality of paths connecting the same ground as one logical path. 2. Trunking means for trunking a plurality of links connecting the same ground to handle one logical link or a plurality of paths connecting the same ground as one logical path. The transmission capacity variable device described. The device operation unit is centrally managed by a network (NW) operation device provided outside the transmission capacity variable device together with the device operation unit of another transmission capacity variable device , and with the NW operation device , the state information, and the setting of the link or path, remove, maintain, or, replace the control information about changes in the state or attribute
Transmission capacity variable device 請 Motomeko 1 wherein. The device operation unit is
A link or path that accommodates a main signal having a high priority and a main signal having main signal priority information having a low priority is assigned to a link or path that accommodates a main signal having main signal priority information having a high priority. the transmission capacity variable device of claim 1 further comprising a means for applying a low priority information is the priority. The device operation unit is
2. The transmission according to claim 1, further comprising means for controlling the assignment of the main signal to the transmission processing unit according to the main signal priority information of each main signal when a plurality of main signals compete for the assignment of the main signal to the transmission processing unit. Variable capacity device. During the said signal distributor and the transmission processing unit, or between the signal transmitting and receiving unit and the signal distributor, e Bei output traffic observation unit for observing the traffic volume,
The device operation unit is
When obtaining the observation result from the output traffic observation unit, comparing the traffic data generated based on the obtained observation result and a preset threshold, and if the traffic data exceeds the threshold, transmission capacity variable device <br/> recited in claim 1, including means for changing the setting of the signal distribution rule of the signal distributor. The device operation unit is
Based on the observation result, the necessary number of links or paths required to accommodate the main signal is calculated, and in order to add or delete the links or paths so as to be the required number, the signal distribution unit and the 8. The transmission capacity variable device according to claim 7 , further comprising means for controlling the transmission processing unit. The output traffic monitoring unit
8. The transmission capacity variable device according to claim 7 , further comprising means for observing any of a traffic volume, main signal priority information, a source address, or a destination address. The transmission capacity variable device according to claim 1, wherein the signal transmission / reception unit is used as a hierarchical network device that handles an upper layer and the transmission processing unit handles a lower layer signal. When main signal priority information is not given to the main signal to be input / output, the main signal group to which main signal priority information is not given is assigned the highest priority in order to distribute the main signal in the signal distributor . The transmission capacity variable device according to claim 1, further comprising a signal distribution rule handled as low main signal priority information . When the path exchange unit is between the signal transmission / reception unit and the signal distribution unit, between the signal transmission / reception unit and the path exchange unit, and when not, the signal transmission / reception unit and the signal distribution unit. The transmission capacity variable device according to claim 1, further comprising an input traffic observation unit that observes traffic characteristics received by each signal transmission / reception unit. The input traffic observation unit is
13. The transmission capacity variable device according to claim 12 , further comprising means for observing the traffic volume and main signal priority information received by each signal transmitting / receiving unit as the traffic characteristics. The signal distribution rule is:
The transmission capacity variable device according to claim 1, wherein application information is used instead of the main signal priority information. The signal distribution rule is:
The transmission capacity variable device according to claim 1, wherein information of the signal transmitting / receiving unit is used instead of the main signal priority information.

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