JPH11346220A - Reconfiguration server and communication node - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a time required for logical reconfiguration for an ATM (asynchronous transfer mode) network. SOLUTION: In the case that a virtual channel handler 201 that terminates a virtual path VP 301 fails to try to extend its capacity by signaling, the VCH 201 makes an extension request to a reconfiguration server 7. Upon the receipt of the extension request, the server 7 makes a capacity decrease request to VCH 202, 204 that terminate respectively other VP 302, 303 via same physical links 501, 502 as those of the VP 301. Upon the receipt of the capacity decrease request, the VCH 202, 204 calculate respectively the required VP capacity, decreases the capacity to the calculated capacity by using signaling, and makes a capacity decrease reply including the capacity reduced value to the server. When the server 7 receives the capacity decrease reply, the server 7 makes an extension reply to the VCH 201 by using a minimum decreased capacity for a possibly increased capacity. The VCH 201 in response to the extension reply selects a sum of the current capacity and the possibly increased capacity as a new VP capacity and extends the VP capacity by signaling.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reconfigurable network, and more particularly to an ATM network capable of logical reconfiguration by changing the capacity of a virtual connection.

[0002]

2. Description of the Related Art A conventional reconfigurable network of this kind is disclosed, for example, in December 1995, IEICE Technical Report SSE95-122, pp. 37-42, "Evaluation of mounting performance of self-sizing operation". The purpose of the present invention is to redistribute communication resources of a physical network provided between virtual paths in order to secure performance in accordance with load fluctuation on virtual paths in an ATM network.

[0003] Here, ATM (asynchronous) is used.
The transfer mode is a system in which a fixed-length block called a cell is used as a unit for multiplexing and exchanging with a physical link, and information is transferred on a virtual connection identified by an identifier described in the cell. The virtual connection includes a virtual path (VP) and a virtual channel (VC). In a cell, a virtual connection identifier is assigned to a virtual path and a virtual channel is assigned to a virtual channel. As a result, a certain virtual path accommodates a plurality of virtual channels. Of course, a certain physical link accommodates a plurality of virtual paths.

FIG. 10 is a block diagram showing the configuration of a conventional reconfigurable network.

A virtual channel (VC) 1, a virtual channel handler (VCH) 2, a virtual path (VP) 3, and a virtual path handler (VPH) 4
, A physical link 5 for accommodating a VP, and a network management system (NMS) 6.

[0006] VCH2 terminates VP3 and changes VC1 to V
Store in P3. Since this accommodation request occurs stochastically, for example, as in the case of a telephone call, accommodation of VC1 in VP3 is not always successful, and performance in VP3 can be obtained with this unsuccessful probability. The product of the frequency of the accommodation request and the required accommodation time is called traffic.

[0007] The VPH 4 terminates the VP 3 and accommodates the VP 3 in the physical link 5. The VP3 is treated as a group of telephone lines, for example, and is accommodated in the physical link 5 of the VP3 deterministically.

[0008] VC1 and VP3 are collectively called a virtual connection, and VCH2 and VPH4 are collectively called a communication node.

When each of the VCHs 2 and VPH 4 receives the capacity setting request message from the NMS 6, it changes the capacity management table. In particular, in the VCH2 terminating the VP3, the traffic shaper for adjusting the cell flow in the VP is changed, and a capacity setting response message is returned after the termination. When receiving the traffic / performance information request message, it returns this to the NMS 6 as a traffic / performance information response message. In this manner, the NMS 6 exchanges messages in a polling format, thereby
2. Manage and control VPH4.

[0010] VCH2 and VPH4 are assigned node numbers that can be uniquely identified in the network, and physical links connected to each node are assigned port numbers that can be uniquely identified within that node. Therefore, a physical link going down from a certain node can be uniquely identified in a network by a set of a node number and a port number. Therefore, a set of a node number and a port number is hereinafter referred to as a physical link number.

The NMS 6 periodically collects traffic / performance information from the VCH 2 and determines the performance to calculate the required VP capacity in order to redistribute resources from VPs with excess capacity to VPs with insufficient capacity. Then, the capacity is set for each of the VPH4 and VCH2. Therefore, the NMS 6 is connected to all the VCHs 2 and VPHs 4 in the network by the VC for management.

FIG. 11 is a block diagram showing a conventional NMS 6.

The NMS 6 is a database (DB) device 1
0, a control device 11, and a message transmitting / receiving device 12.

The DB device 10 is a traffic DB 101
And a topology DB 102 and a route list DB 103.

FIG. 12A shows the traffic DB 101.
As shown in (1), information on traffic and performance of each VP3 in the network collected from each VCH2 is held in a table composed of entries of VP number | traffic information | performance information | VP capacity. Here, the VP number is composed of a set of a node number, a port number, and a VP identifier that can be uniquely identified by the port number.
Uniquely identified within the network.

As shown in FIG. 12 (B), the topology DB 102 stores the connection relationship between the VCHs 2 and VPH 4 and the free capacity of the physical link 5 connecting the VCHs 2 and VPH 4 as node number | physical link number of adjacent node | Held in a table consisting of

As shown in FIG. 12 (C), the via list DB 103 comprises a via list in which the physical link numbers of the respective VPs in the network are arranged in order, with entries of VP number | physical link number. To be kept in the table.

The control device 11 includes a capacity management unit 111, a performance management unit 112, a capacity calculation unit 113, and a capacity setting unit 1.
14 and a reduction candidate selection unit 115.

The performance management unit 112 periodically collects the traffic and performance of the VC1 housed in the VP3 where the VCH2 terminates in a polling format, and collects the traffic DB1.
01 has been updated. In addition, according to an instruction from the capacity management unit 111, the performance information of the VP3 is extracted from the traffic DB 101, and it is determined whether the performance is satisfied.

The capacity calculation unit 113 extracts the traffic information and the performance request of the VP3 specified by the capacity management unit 111 from the traffic DB 101, calculates the required VP3 capacity, and if necessary, calculates the VP3 of the track DB 101.
Update capacity.

The capacity setting unit 114 stores all Vs specified in the via list of the VP 3 specified by the capacity management unit 111.
A capacity setting request message is sent out to PH4 and VCH2 in order to set the capacity, and these VPH4 and VCH2 are set.
When the capacity setting response message is returned from all of CH2, the VP capacity is updated in the traffic DB 101, and the VP3 is updated in the topology DB 102.
Update the free space of all the physical links 5 that pass through.

The reduction candidate selection section 115 stores the route list DB
With reference to 103, the extension candidate V for which the via list has been designated
It is checked whether there is another VP3 accommodated in the same physical link as the P3, and if so, a route list of the VP3 is extracted.

The capacity management unit 111 includes a performance management unit 12
By using the capacity calculation unit 113, the capacity setting unit 114, and the removal candidate selection unit 115, it is determined whether the VP capacity is to be added or removed, and the capacity is added or removed.

The message transmitting / receiving device 12 includes a message transmitting unit 121 and a message receiving unit 122.

The message transmission / reception device is connected to all VCHs 2 and VPHs 4 in the network by a management VC.

The message transmitting unit 121 is connected to each VCH2,
Sends a request message to VPH4. The message receiving unit 122 receives a response message from each of the VCH2 and VPH4.

Next, the operation of the NMS shown in FIG. 11 will be described with reference to FIG.

Using the performance management unit 112, the capacity management unit 111 refers to the traffic DB 101 to determine whether a performance requirement is satisfied for a certain VP3 (step A1). If so, end.

If it is determined in step A1 that the performance requirement is not satisfied, the capacity management unit 111 uses the capacity calculation unit 113 as a candidate
The capacity is calculated, and the difference between the newly calculated capacity and the current capacity value is set as an expansion request value (step A2).

Next, the capacity management unit 111
With reference to B102, it is checked whether or not there is enough free space for all the physical links 5 that the VP3 passes through to satisfy the expansion request value calculated in step A2 and expansion is possible (step A3). If it is possible, go to step A10.

If the extension is not possible in step A3,
The capacity management unit 111 uses the removal candidate selection unit 115 to
Another V that goes through the same physical link 5 as the VP of the extension candidate
Assuming that P3 is a reduction candidate, the VP number and the number of the shared physical link are selected. Then, it is determined whether at least one reduction candidate is found (step A4). If there is no reduction candidate, the process ends.

At step A4, if there is a reduction candidate,
The capacity management unit 111 uses the capacity calculation unit 113 to calculate the required VP capacity for each VP5 that is a reduction candidate (step A5).

Next, the difference between the newly calculated capacity and the current capacity is calculated for each reduction candidate VP, and it is determined whether there is a VP3 whose value becomes negative and the capacity can be reduced. Check (step A6), and if there is no candidate, the extension candidate V
Since the capacity increase for P is not possible, the process ends.

In step A6, if there is a VP3 that can be removed, the capacity management unit 111 determines the difference between the previously calculated VP capacity and the number of the physical link 5 that the removal candidate VP shares with the extension candidate VP. , By referring to the route list of the extension candidate VP, and calculating the total sum of the capacity that can be newly used by the capacity reduction of the reduction candidate VP in each physical link through which the extension candidate VP passes, and calculates the minimum value of these minimum values. It is assumed that the VP capacity can be increased. Then, the smaller one of the expansion allowance value and the expansion request value calculated in step A2 is set as the expansion possible value (step A7). This is to prevent the required value for addition from being increased by accident.

Next, the possible addition value is not 0, and it is checked whether or not addition is possible (step A8).

If the expandable value is not 0 in step A8 and the expansion is possible, the capacity management unit 111
4, the capacities of all VP4s that can be reduced are set to the values newly calculated in step A5 (step A9), and the procedure goes to step A10.

In step A10, the capacity management unit 111
Sets the total capacity of the expandable value calculated in step A7 and the current capacity as a new capacity and sets the capacity using the capacity setting unit 114.

Next, the operation of the prior art shown in FIG. 10 will be described.

The capacity management unit 111 in the reconfiguration server 7
It is determined whether or not the performance of the VP 301 is satisfied by using the performance management unit 112 (step A1). Since it is determined that the performance is not satisfied, it is desired to increase the capacity. Since there is no capacity and expansion cannot be performed as it is, another V sharing the physical links 501 and 502 using the reduction candidate selection unit 115.
P302 and 303 are selected, and then the capacity of the VPs 302 and 303 is calculated using the capacity calculation unit 113 (step A5).

As a result, the VPs 302 and 303 can be reduced, and the capacities of the physical links 501 and 502 are solved. The smaller one of the values is set as the additional value of the VP 301 (step 7).

Next, the capacity management unit 111
2, VPH401, 404, 403, VCH203 and VCH204, VPH402, 404, 403, VC
An instruction is issued to H205 to reduce the VPs 302 and 303, respectively (step A9).

Finally, the capacity management unit 111
An instruction is issued to the VPs 301 and 206 to add the VP 301 (step A10).

[0043]

A problem with the conventional reconfigurable network is that it is not possible to ensure performance while following fast traffic fluctuations.

The reason is necessary for the reallocation of capacity,
The NMS collectively and sequentially executes all procedures of performance management, capacity calculation, capacity setting, and reduction candidate selection, and performs a series of these operations on the connection between the physical link and the communication node and the free capacity of the physical link. Information, information on the physical link passed by the virtual connection, and information on traffic / performance are executed while searching / updating a database registered for the entire network, thereby increasing the capacity of the virtual connection whose performance is not satisfied. This is because the time required for completion is longer.

It is an object of the present invention to provide a network in which reconfiguration is performed quickly.

[0046]

According to the first reconfigurable network of the present invention, the performance management of the virtual connection, the calculation of the required capacity, and the addition / reduction of the capacity are performed by communication for terminating the virtual connection. This is performed by the node, and the reconfiguration server only selects the reduction candidate VP.

More specifically, the communication node terminating the virtual connection has a performance management means (142 in FIG. 2A) for judging the necessity of the capacity expansion, and the necessity of the expansion. A capacity calculating means (113 in FIG. 2A) for calculating a capacity required when the judgment is made, and a capacity setting means (143 in FIG. 2A) are provided, and the reconfiguration server is set in the network. And a reduction candidate selection unit (172 in FIG. 2B) for selecting another VP accommodated in the same physical link from all the VPs.

The second reconfigurable network according to the present invention is capable of not only managing the performance of the virtual connection, calculating the required capacity and increasing / decreasing the capacity, but also selecting the reduction candidate VP. Is performed by the termination device.

More specifically, the communication node that terminates the virtual connection is a performance management unit (14 in FIG. 6).
2), calculation means (113 in FIG. 6), capacity setting means (143 in FIG. 6), and VPs contained in the physical link included in the reduction request message from the terminated VPs
And a communication node terminating another virtual connection, in order to make a reduction request to all communication links passing through the virtual connection determined to be an expansion candidate. Generating means (203 in FIG. 6) for generating a message including a set.

The calculation of the capacity required for each VP and the change of the capacity are performed in a distributed manner by the VCHs that terminate the
In order to enable the capacity of P to be increased, only the VP to be reduced is selected by the reconfiguration server provided in the network.

Alternatively, when selecting a VP to be reduced, the VCH terminating the extension candidate VP notifies all other VCHs of the set of all physical links through which the VP passes, and sets each VCH. To be performed.

[0052]

FIG. 1 is a block diagram showing a reconfigurable network according to a first embodiment of the present invention. VC1, VCH2, VP3, VPH4
, A physical link 5, and a reconfiguration server 7.

VCH2 and VPH3 change the VP capacity of VP3 by signaling. This is specifically performed in the following procedure.

First, the VCH 2 terminating the VP 3 generates a capacity change request message and transfers it to the next node VPH 4 on the route.

If the capacity can be changed on the physical link 5 connected to the VPH 4, the capacity is changed and the capacity change request message is transferred to the next node VPH 4.

If the capacity cannot be changed on the transferred node, the capacity change response message indicating the failure of the capacity change is returned in the reverse direction on the route to which the capacity change response message has been transferred.

Each node that has received the capacity change response message indicating the failure of the capacity change returns to the original capacity, and returns to the VCH 2 that issued the capacity change request message.
Returns a capacity change response message.

When the capacity change request message is transferred to VCH2 terminating VP3 on each physical link on the route after the capacity change succeeds, the VCH2
A capacity change response message indicating a successful capacity change is returned to VCH2 that transmitted the capacity change request message.

The VCH 2 collects and monitors traffic and performance information in the terminating VP 3, calculates the required VP capacity from the traffic information and the performance standard, and changes the terminating VP capacity by signaling. If the addition fails, an increase request message is transmitted to the server 7, and when the expansion response message returns, the capacity is increased to the value.

The reconfiguration server 7 is connected to all the VCHs 2 in the network by VCs for management.

When the VCH 2 initializes the VP 3 by signaling, it registers the via list in the reconfiguration server 7.

When the reconfiguration server 7 receives the addition request message from the VCH 2, the reconfiguration server 7 extracts another VP 3 sharing the same physical link 5 as a reduction candidate, and terminates the V that terminates it.
A reduction request message is sent to CH2. When the reconfiguration server 7 returns the relocation response message from the VCH 2 to which the reconfiguration server 7 has transmitted the relocation request message, the reconfiguration server 7 transmits an expansion response message including the expansion value to the VCH that has requested the expansion.
Return to 2.

FIG. 2A is a block diagram showing a configuration of VCH 2 according to the first embodiment of the present invention.

The VCH 2 includes the DB device 13 and the control device 1
4, a message transmitting / receiving device 15, a switch 22,
And an internal interface 23.

The DB device 13 comprises a traffic DB 101.

In the traffic DB 101,
When a new setting / capacity change of a VP is performed by signaling, the VP capacity is registered / changed.

The control device 14 includes a capacity management unit 141, a capacity calculation unit 113, a performance management unit 142, a connection control unit 143, and a message generation unit 144.

The connection control unit 143 transmits and receives a signaling message through the message transmission unit 151 and the message reception unit 152, thereby transmitting the VP3
Of the new VC2 and the setting of the new VC2 in the VP4. In resetting the capacity of the VP3, the interface device 23 is instructed to readjust the cell flow in VP units, and the parameters of the traffic shaper are changed.
When a new VC2 is set, an identification number of the VC in the VP is set.

The performance management unit 142 determines that the traffic that is the frequency of occurrence of a request to newly set a VC in each VP terminated by the VCH 2 and that there is not enough free space to set a new VC in the VP. Information on the call loss rate, which is the rate at which the setting request is rejected, is measured based on information from the connection control unit, and the transistor DB 101 is updated. Also, according to an instruction from the capacity management unit 141,
With reference to the traffic DB 101, it is determined whether the performance of the VP3 satisfies the request.

The message generator 144 generates an expansion request message and a reduction response message to the reconfiguration server 7.

The capacity management section 141 has the capacity calculation section 113
The capacity management unit 142, the capacity setting unit 143, and the message generation unit 144 are used to determine whether to increase or decrease the capacity, and to increase or decrease the capacity.

The message transmitting / receiving device 15 includes a message transmitting unit 151 and a message receiving unit 152.

The message transmitting section 151 is provided for the capacity setting section 14.
3 transmits a signaling message generated to VPH4 directly connected to VCH2. In addition, it transmits an expansion request or reduction response message passed from the capacity management unit 141 to the reconfiguration server 7.

Message receiving section 152 receives a signaling message from VPH 4 to which VCH 2 is directly connected, and passes it to capacity setting section 143. Further, when a message of an expansion response or a reduction request is received from the reconfiguration server 7, the message is passed to the capacity management unit 141.

The switch 22 guides a fixed-length cell, which is a unit of information transfer, from an incoming input port to a desired output port in an ATM.

The interface device 23 performs traffic shaping so that the cell flow in the VP 3 does not exceed the allocated capacity and is transmitted to the physical link. Also,
When a new VC1 is set in the VP3, a VC identification number is set.

FIG. 2B is a block diagram showing the configuration of the server according to the first embodiment of the present invention.

The reconfiguration server 7 selects the VCH 2 terminating the capacity reduction candidate VP based on the capacity increase request, instructs the capacity reduction, and is notified from the VCH 2 terminating the capacity reduced VP 4. Based on the capacity reduction amount, the capacity increase possible amount is notified to VCH2 requesting the capacity increase.

The reconfiguration server 7 includes a DB device 16, a control device 17, and a message transmitting / receiving device 18.

The DB device 16 includes a route list DB 103 and a current DB 161.

FIG. 3A shows the format of a control message exchanged between the VCH 2 and the reconfiguration server 7 and information in each message. The format is the extension / reduction bit | request / response bit | reduction / extension candidate V
P number | extension request / response value / removal response value (however, for a reduction request, don't care).

As shown in FIG. 3B, the current DB 1
Numeral 61 indicates the physical link through which the VP for which the expansion request has been made and the free capacity newly secured in the physical link 5 by the reduction of the reduction candidate VP passing therethrough. It is stored in a table composed of entries of number | physical link number | free capacity.

Here, as described in the prior art, the physical link number is specified by a combination of the node number and the port number.

The current DB 161 is cleared when the extension value is determined.

The control device 17 includes a capacity management unit 171, a reduction candidate selection unit 172, and a message generation unit 173.

[0086] The reduction candidate selection unit 172 stores the route list DB.
Referring to 103, if there is another VP accommodated in the same physical link as the addition candidate VP whose number is specified in the addition request message, it is set as a deletion candidate VP and the VP
Each time, for example, a node number having a smaller value among a pair of VCHs 2 terminating the same and a physical link number common to the extension candidate VP are extracted.

The message generation unit 173 generates a reduction request message addressed to the VCH selected by the reduction candidate selection unit and an expansion response message addressed to the VCH 2 requesting the expansion.

The capacity management unit 171 is the link sharing determination unit 1
72 and the message generation unit 173,
It notifies the VCH2 terminating P of the reduction request message, and notifies the VCH2 requesting the expansion of the expansion response message.

The message transmitting / receiving unit 18 includes a message transmitting unit 181 and a message receiving unit 182.

The message transmission section 181 is provided for the capacity management section 1
Each of the reduction request message and the expansion response message created by the 71
2, and transmission to the VCH2 that requested the addition.

The message receiving unit 182 passes the reduction response message and the expansion request message received from the VCH 2 that has transmitted the expansion request to the capacity management unit 171.

Next, an operation example according to the first embodiment of the present invention will be described with reference to FIG.

FIG. 4A is a flowchart showing an operation example in VCH2.

Using the performance management unit 142, the capacity management unit 141 refers to the traffic DB 101 to determine whether a performance request is satisfied for a certain VP3 (step A1). If so, end.

If it is determined in step A1 that the performance requirement is not satisfied, the capacity management unit 141
Is used as an expansion candidate, the required VP capacity is calculated using the capacity calculation unit 113, and the difference between the newly calculated capacity and the currently allocated capacity is set as an expansion request value (step A2).

Next, the capacity management unit 141 uses the connection control unit 143 to attempt to increase the capacity to the expansion request value calculated in step A2 (step B1), and ends the process if it succeeds.

If the capacity expansion fails in step B1, the capacity management unit 141 creates an expansion request message using the message generation unit 144, and passes it to the message transmission unit 151 (step B2).

[0098] The capacity management unit 141
If the message is passed from the server 52 (step B3), it is checked whether the message is an extension response message (step B4). If so, the procedure goes to step A8. If not, the procedure goes to step B6.

In step A8, it is checked whether the expansion response value is not 0 and the expansion is possible by looking in the message.

In step A8, if the expansion response value is not 0 and expansion is possible, the capacity management section 141 uses the capacity setting section 143 as a new capacity by adding the expansion response value to the current capacity. A new capacity is set for the lever (step B6).

In step B6, the capacity management unit 141
It is determined whether or not the message passed from the message receiving unit 152 is a reduction request message. If not, the process ends.

If the message is a removal request message in step B6, the capacity management unit 141 uses the capacity calculation unit 113 to calculate a new capacity for the removal candidate VP3 whose number is specified in the message (step S6). A5).

Next, the capacity management unit 141 checks whether the calculated capacity is smaller than the current capacity and can be reduced (step A6), and if not, sets the reduction response value to 0 and goes to step B8.

If the removal is possible in step A 6, the capacity management section 141 sets the difference between the current capacity and the calculated capacity as the removal response value, and uses the connection control section 143 to reduce the removal response value. Is reduced (step B9), and the procedure goes to step B10.

In step B10, the capacity management unit 141
Generates a reduction response message using the message generation unit 144 and passes the message to the message transmission unit 151 (Step B10).

Hereinafter, the operation of the reconfiguration server will be described with reference to FIG.

The capacity management unit 171 is provided with the message receiving unit 1
If a message is received from 82 (step B3),
Check whether the message is an expansion request message (step B
9) If yes, go to step B10; if not, go to step B12.

At step B10, the capacity management unit 171
Using the link sharing determination unit 172, if there is another VP3 that passes through the same physical link as the extension candidate VP3 whose number is specified in the extension request message, the VP3 And VCH2 that terminates it
Of the node with the smaller value and the number of the physical link shared with the extension candidate VP,
Register to 1.

Next, the capacity management unit 171 uses the message generation unit 173 to select a reduction candidate VP and a VCH 2 that terminates the reduction candidate VP. Then, it is checked whether or not there is a reduction candidate (step B10).

If no reduction candidate is found in step A4, the expansion value is set to 0 (step B11), and the procedure goes to step B17.

In step A4, if at least one reduction candidate VP can be selected, a reduction request message is generated to the extracted VCH2 that terminates the reduction candidate VP3, and is sent to the message transmission unit 181. At the same time, the number of reduction candidate VPs for the expansion candidate VP is set to the response variable N (step B11).

In step B13, the capacity management section 171 checks whether the message received from the message receiving section 182 is a reduction response message, and if not, ends.

In step B13, if the message received from the message receiving unit 182 is a reduction response message, the capacity management unit 171 determines in the current DB 161 the same reduction candidate VP whose number is specified in the reduction message. A reduction response value is set to the solution capacity for all physical link numbers corresponding to the numbers (step B1).
4).

Next, 1 is subtracted from the response variable N indicating the number of VPs for which a reduction response has been made, and it is checked whether or not the value is 0 (step B15). Terminates because no response has been returned for.

If the value obtained by subtracting 1 from the response variable at step B15 becomes 0, since the responses have returned from all the VPs requesting the reduction, the capacity management unit 171 sets the current D
With reference to B161, the solution capacities are summed up for each of the same physical link numbers to obtain an extension allowance value, and the smaller one of the extension allowance value and the extension request value specified in the extension request message is used as the extension response value. At the same time, the current DB 161 is cleared (step B16).

Next, an expansion response message is generated by using the message generation unit 173 to the VCH 2 that has transmitted the expansion request message, and passed to the message transmission unit 181 (step B17).

The effect of the first embodiment of the present invention will be described. In the first embodiment of the present invention, the VCH 2 that terminates the VP 3 performs the performance management of the VP 3 and calculates the required capacity, and the VC that terminates the VP also increases or decreases the capacity.
Since this is performed using signaling activated by H2, the time required for network reconfiguration is reduced.

Next, the operation of the first embodiment of the present invention will be described in detail.

In FIG. 1, the capacity management unit 141 in the VCH 201 uses the performance management unit 142 to check whether or not the performance is satisfied (step A1). VP3 using
An attempt to increase the capacity of 01 failed. Therefore, VP3
01 is generated as an expansion candidate VP, and an expansion request message is generated and passed to the message transmission unit 151 (step B2).
An expansion request message is transmitted to the reconfiguration server 7.

When the capacity management unit 171 in the reconfiguration server 7 receives this addition request message from the message reception unit 182, it uses the link sharing determination function 115 to make a physical connection with the VP 301 that is the expansion candidate VP specified in the message. Other VPs 302,3 sharing links 501,502
03, and further terminates VPs in VCH2
VCH 202,2 having a node number with a small value in
04 is selected (step B10).

Next, the capacity management unit 171
Then, a reduction request message in which the VPs 302 and 303 are set as reduction candidates is generated and passed to the message transmitting unit 181 (Step B11), and the reduction request message is transmitted to the VCHs 202 and 204.

When the VCH 202 receives the reduction request message from the message receiving unit 152, the capacity management unit 141 uses the capacity calculation unit 113 to calculate a new capacity for the VP 302 specified in the message (step). A5).

Next, since the capacity can be reduced from the current capacity,
The capacity management unit 141 uses the capacity setting unit 143 to
02 (step B7), and then, using the message generation unit 144, generates a reduction VP 302 and a reduction response message in which the amount of reduction is described, and generates a message transmission unit 151.
(Step B8).

Similarly, the steps A5, B7, and B8 are also performed on the VCH 204.

In the reconfiguration server 7, when all of the removal response messages for the addition candidate VP 301 have returned, the capacity management unit 141 sets the smaller one of the reduction amounts of the VPs 202 and 203 as the addition value, and Using the generation unit 173, an expansion response message is generated and passed to the message transmission unit 181 (step B17).
01 is transmitted.

In the VCH 201, the capacity management unit 141
When the extension response message is passed from the message receiving unit 152, the extension possible value is not 0 and the extension can be performed by looking in the extension response message.
P301 is added (step B5).

A second embodiment of the present invention will be described with reference to FIG.

VC1, VCH2, VP3, VPH
4 and a physical link 5. Each VPH, VC
H is a node number.

The difference from the first embodiment is that the reconfiguration server 7 is not provided, and the VCH 2 includes a reduction request value or a reduction response value of a terminating VP capacity and a reduction list including a route list as necessary. The point is that a message for a setup request / response is generated and directly exchanged with all other VCHs. For this reason, a dedicated communication path for exchanging messages for reduction request / response with each other is set for all VCHs 2 in the network.

FIG. 6 is a block diagram showing how to set a communication channel between VCHs 2.

In FIG. 6A, VCHs 201 to 206 are connected to each other by dedicated one-to-one dedicated VCs 101 to 105. The removal request message is individually transmitted to all the other VCHs 2 using a dedicated one-to-one dedicated VC.

When returning the reduction response message to the VCH 2 that has notified the reduction request message, one-to-many transmission is to be performed by referring to the node number included in the higher rank of the reduction candidate VP number to be responded to. The dedicated VC is selected and transmitted to the VCH2 that has notified the reduction request message.

In FIG. 6B, VCHs 201 to 206
Is a one-to-one dedicated V with the multicast server 8
C117 to 122 are connected. Further, a one-to-many dedicated VC 116 is connected to all the VCHs 201 to 206 from the multicast server 8. The multicast server 8 uses a one-to-one dedicated VC
The reduction request message received from H is multicast to all VCHs using the VC 110. In addition, the multicast server 8 transfers the reduction response message received from a certain VCH using the one-to-one dedicated VC, to the VCH that has requested the reduction using the one-to-one dedicated VC. This is because, for example, the one-to-one dedicated VCH to be transmitted is selected with reference to the node number included in the higher order of the reduction candidate VP number in the reduction response message, and the VCH2 that has notified the reduction request message is transmitted to the VCH2. Send.

The number of the physical link 5 through which each VP 3 terminating the VCH 2 passes is indicated by a signaling message when the VP 3 is initialized by signaling.
Are notified to both VCHs 2 terminating the communication, or are notified from the network management system or the like.

FIG. 7A shows the format of a message exchanged between each VCH2. | Reduction request / response bit | reduction request / response value | hop number | physical link number | ... | physical link number | here,
The number of hops is equal to the number of physical link numbers described in the message. In particular, in the case of a reduction response, the expansion candidate VP
Only the physical link number common to the above is described.

FIG. 8 shows a second embodiment of the present invention.
FIG. 3 is a block diagram illustrating a configuration in a VCH.

VCH2 is composed of the DB device 19 and the control device 2
0, a message transmitting / receiving unit 21, and an internal interface 22.

The DB device 19 is a traffic DB 101
And a via list DB 103 and a current DB 191.

As shown in FIG. 7B, the current DB 191 is composed of a table including entries of physical link number | capacity. This table is cleared when the additional value is determined.

The control device 20 includes a capacity calculation unit 113, a performance management unit 142, a connection control unit 143, a capacity management unit 201, a reduction candidate selection unit 202, and a message generation unit 203.

The removal candidate selection unit 202 is provided with a route list DB
Referring to 103, if there is another VP 3 that passes through the same physical link 5 as the extension candidate VP whose number is specified in the reduction request message, that VP 3 is set as the reduction candidate VP.
The number and the physical link number are extracted.

The message generation unit 203 includes a removal request message including a route list composed of a set of an extension request value and a physical link number through which the candidate VP passes, and a removal response value, the extension candidate VP, and the removal. A reduction response message including a set of physical link numbers common to the candidate VPs is generated and passed to the message transmission unit 211.

The capacity management unit 201 includes a performance management unit 141,
Using the capacity calculation unit 113, the capacity setting unit 143, the link sharing determination unit 115, and the message generation unit 203,
The necessity judgment and setting of the VP capacity increase / decrease are performed.

The message transmission / reception unit 21 includes a message transmission unit 211 and a message reception unit 212. Both can internally return a reduction request message for the own VCH.

The message transmitting section 211 transmits the signaling message generated by the connection control section 143 to the adjacent VPH 4. Also, the message generation unit 20
3 is generated by all other VCH2s.
And sends a removal response message to V
Transmit to CH2.

[0146] The message receiving section 212 is connected to the adjacent VPH4.
Is passed to the connection control unit 143. In addition, a reduction request message or a reduction response message received from another VCH 2 is passed to the capacity management unit 201.

Next, the operation in VCH2 will be described with reference to FIG.

In FIG. 9, the capacity management unit 201 determines whether or not a performance request is satisfied for a certain VP 3 using the performance management unit 142 with reference to the traffic DB 101 (step A1). If determined,
finish.

If it is determined in step A1 that the VP is not satisfied, the capacity management unit 201 uses the capacity calculation unit 113 to calculate the necessary VP capacity using the VP as an extension candidate, and calculates the newly calculated VP capacity. The difference between the capacity and the currently allocated capacity is determined as an increase request value (step A2).

Next, the capacity management unit 201 attempts to increase the VP capacity to the expansion request value calculated in step A2 by using the connection control unit 143 (step B1). Update the VP capacity and end.

If the capacity expansion has failed in step B1, the capacity management unit 201 generates a reduction request message using the message generation unit 202, passes the message to the message transmission unit 211, and sends the message to the increase candidate VP. The timer is started (Step C1).

In FIG. 9, when the capacity management unit 201 receives a message from the message receiving unit 211 (step B3), it checks whether it is a reduction response (step C).
2) If yes, go to step C3; otherwise, go to step B6.

In Step C3, the capacity management unit 201
It is checked whether a timeout has occurred for the increase candidate VP3, and if so, the process ends.

If the timeout has not occurred in step C3, the set of the physical link number and the capacity in the reduction response message is registered in the current DB 191 (step B14).
finish.

In step B6, the capacity management unit 201
It is checked whether the message is a removal request message, and if not, the process ends.

If it is determined in step B6 that the message is a removal request message, the capacity management unit 201
, The increasing candidate V numbered in the message
It is checked whether or not there is a VP3 sharing the same physical link as P (step C4). If not, the process ends.

If there are any VPs that pass through the same physical link as the extension candidate VP in step C5, all of them are extracted and set as reduction candidate VPs, and the necessary VP capacity is calculated (step A
5).

Next, for each of the reduction candidates VP, the calculated capacity is smaller than the current capacity, and the V that can be reduced is selected.
It is checked whether there is P (step A6), and if there is no P, the process ends.

If there is a VP that can be reduced in step A6, the difference between the current capacity and the newly calculated capacity is used as the reduction response value, and each VP is terminated on the other end.
If the number is smaller than
The capacity management unit 201 uses the capacity setting unit 113 to
The VP capacity for the reduction response is reduced every time (step C
5).

Next, the capacity management unit 201 uses the message generation unit 203 to store the route list of the extension candidate VP,
A reduction response message including a set of physical link numbers common to the route list included in the reduction request message and the reduction response value is generated to the VCH 2 that has issued the reduction request, and passed to the message transmitting unit 211 (step C6).

In FIG. 9, when a timeout occurs for the extension candidate VP3 (step C7), the capacity management unit 201
Refers to the current DB 191, calculates the sum of the capacities of the respective physical links, and sets the minimum value of the sum as the expansion allowable value. Then, the smaller one of the required expansion value calculated in step A2 and the allowable expansion value is set as the allowable expansion value (step B16).

Next, it is checked whether or not the value that can be added is 0 (step A8).

If the expandable value is not 0 in step A8, expansion is possible. Therefore, the capacity management unit 201 sets the sum of the expandable value and the current capacity as a new capacity, and uses the connection control unit 143 to set the new capacity. A large capacity is set (step B5).

Next, the effect of the second embodiment of the present invention will be described. The second embodiment of the present invention provides, in addition to VP performance management, calculation of required capacity, and addition / reduction of capacity,
Since each VCH 2 also selects a VP to be a reduction candidate, the time required for reconfiguration is further reduced. In addition, since a series of procedures required for network reconfiguration are all performed in a parallel and distributed manner, reliability is improved as compared with centralized reconfiguration.

Further, since the multicast server 8 is used to transfer the reduction request message to all the VCHs 2, the required number of VCs is smaller than the number of required VCs compared to the case where one-to-one dedicated VCs are individually set between the VCHs 2. From the square of the number
H is reduced to a number proportional to the number of H, and even when a new VCH2 is added, one-to-one dedicated V
It is not necessary to set C, and only two VCs, one-to-one and one-to-many, need to be set with the multicast server 8, so that the expandability and flexibility of the reconfigurable network are increased.

Further, the reduction request message is sent to all other Vs.
Each dedicated VC 101-1 to transfer to CH 2
15 can be transferred quickly to the multicast server 8 instead of individually transferring to the multicast server 8. In addition, by managing the connection between the VCH 2 and the multicast server 8, new addition of the VCH to the group constituted by the VCH 2 which meets the bandwidth flexibility /
You can manage your withdrawal.

Next, the operation of the second embodiment of the present invention will be described in detail with reference to FIG. In FIG. 5, VC
In H201, the capacity management unit 201
Is used to check whether the performance is satisfied (step A1), and it is determined that the performance is not satisfied. Therefore, an attempt to increase the capacity of the VP 301 using the connection control unit 143 has failed. Therefore, using the message generation unit 202, the VP 301 is set as an increase candidate, and the route list (VCH 201, VPH 401, 404, 403, VC
H206) is generated, passed to the message transmission unit 211 (step C1), and transmitted to all the other VCHs 202 to 206.

In the VCH 203, when the capacity management unit 201 receives the reduction request message transmitted by the VCH 201 from the message reception unit 212, the capacity management unit 201 uses the link sharing determination unit 144 to specify the increase candidate VP301 specified in the message.
Similarly, when the VP 302 passing through the physical link 501 is selected and it is checked whether or not there is a candidate VP for removal (step C4), it is found that there is a candidate VP. Step A5).

Next, the capacity management unit 201 determines from the newly calculated capacity of the VP 302 and the current VP capacity that it is possible to reduce the capacity, and sends the VP 302 to another VCH 203 that terminates the other. Also has a small node number,
The VP capacity is reduced by signaling using the capacity setting unit 143 (step C5), and a reduction response message including the reduction amount and the common physical link 501 is generated by the message generation unit 202, and the message transmission unit 211 (step C6), and transmits to the VCH 201.

Step C4, Step A5, Step B
7. The same procedure as in step C5 is also performed in the VCH 204, the VP 302 is reduced, and a reduction response message including the reduction amount and the common physical link 502 is sent to the VCH 20.
1 is transmitted.

In the VCH 201 that has issued the reduction request, the capacity management unit 201 sends the message
When the reduction response message is passed from 2, the reduction capacity is registered in the physical link 501 in the current DB 161 by checking the reduction amount in the message. Similarly, VCH2
When the removal response message is passed from 04, the solution capacity is registered in the physical link 502.

When the timer times out, the capacity management unit 201 refers to the current DB 161 and uses the smaller one of the solution capacities of the physical links 501 and 502 as an additional value (step 15), and uses the connection control unit 143. The extension is performed (step B5).

[0173]

The first effect is the reconfiguration of the network,
Especially when it is determined that capacity expansion is necessary for a certain virtual connection, unnecessary parts are released from the virtual connections with excess capacity, and the time required to complete the capacity expansion is reduced, resulting in rapid traffic fluctuation. , It is possible to ensure the performance in each virtual connection.

The reason is that the communication node terminating the virtual connection determines the virtual connection for which the capacity is to be increased and calculates the necessary capacity, and the capacity is changed by the signaling activated by the communication node terminating the virtual connection. Be executed. Therefore, the calculation of the capacity required for the reconfiguration of the network and the expansion of the capacity are performed in a distributed and parallel manner at each communication node that terminates and relays the virtual connection, and information that needs to be searched / updated for that purpose is also distributed. It is because it is arranged.

The second effect is that the time required for the reconfiguration of the network is further reduced and the reliability of the reconfiguration of the network is improved.

The reason is that the selection of the virtual connection whose capacity is to be reduced is also performed by the communication node terminating the virtual connection, so that a series of operations necessary for network reconfiguration are all executed in a distributed and parallel manner. Therefore, all the information to be searched / updated is distributed and arranged, and devices and functions for executing intensive work on the entire network become unnecessary.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration and an operation example of a network according to a first embodiment of the present invention.

FIG. 2A is a block diagram illustrating a detailed configuration of a VCH according to the first embodiment of the present invention, and FIG. 2B is a detailed diagram of a reconfiguration server according to the first embodiment of the present invention; FIG. 2 is a block diagram showing a configuration.

FIG. 3A is a diagram showing a table configuration of a current database according to the first embodiment of the present invention, and FIG.
FIG. 3 is a diagram showing a format of a control message according to the first embodiment of the present invention.

FIG. 4A is a flowchart illustrating an operation of a VCH according to the first embodiment of the present invention, and FIG. 4B is a flowchart illustrating an operation of a server according to the first embodiment of the present invention.

FIG. 5 is a block diagram showing a configuration and an example of a network according to a second embodiment of the present invention.

FIG. 6 is a block diagram showing a connection form between VCHs according to the second embodiment of the present invention.

FIG. 7A is a diagram showing a format of a control message according to the second embodiment of the present invention, and FIG. 7B is a diagram showing a table configuration of a current database according to the second embodiment of the present invention; .

FIG. 8 is a block diagram showing a detailed configuration of a VCH according to the second embodiment of the present invention.

FIG. 9 is a flowchart illustrating an operation of a VCH according to the second embodiment of the present invention.

FIG. 10 is a block diagram showing a configuration and an operation example of a conventional network.

FIG. 11 is a block diagram showing a detailed configuration of a network management system in a conventional example.

12A is a diagram illustrating a table configuration of a traffic database, FIG. 12B is a diagram illustrating a table configuration of a topology DB, and FIG. 12C is a diagram illustrating a table configuration of a route list;

FIG. 13 is a flowchart illustrating the operation of a network management system in a conventional example.

[Explanation of symbols]

101 to 115 VC for one-to-one connection between VCHs 116 Multicast server / VC for one-to-many connection between VCHs 117 to 122 VC for one-to-one connection between VCH and multicast server 201 to 203 Virtual channel handler (VC)
H) 301 to 303 Virtual path (VP) 401 to 404 Virtual path handler (VPH) 501 to 503 Physical link 6 Network management system (NMS) 7 Reconfiguration server 8 Multicast server 10, 13, 16, 19 Database device 101 Traffic database 102 Topology database 103 Via list 161,191 Current database 11,14,17,20 Controller 111,141,171,201 Capacity management unit 112,142 Performance management unit 113 Capacity calculation unit 114,143 Capacity setting unit 115,172, 202 Deletion candidate selection unit 144, 173, 203 Message generation unit 12, 15, 18, 21 Message transmission / reception device 121, 151, 181, 211 Message transmission unit 122, 152, 82,212 message receiving unit 22 switch 23 interface device

Claims (3)

[Claims] 1. A database that retains information about a physical link through which a virtual connection passes, information about a communication node that terminates the virtual connection, and the database is referred to, and it is determined that the capacity needs to be increased. Selecting means for respectively selecting another virtual connection accommodated in the same physical link as the virtual connection and the communication node terminating the other virtual connection; and A deletion request message including information for notifying the communication node, a virtual connection for which an expansion request has been made, and an expansion response value relating to a value of a capacity that can be expanded with respect to the virtual connection, are included in the request of the expansion request. Virtual connection And a message generating means for generating an expansion response message including information for notifying a communication node that terminates the communication node. The communication node other than the communication node that terminates the virtual connection for which the expansion request has been made, A reconfiguration server, wherein the determination is made based on a reduction response value included in the reduction response message received from the communication node and an expansion request value included in the expansion request message received from the communication node. 2. A performance management means for terminating or relaying a virtual connection, monitoring information on traffic and performance of the virtual connection and judging the necessity of capacity expansion, and determining a capacity to be allocated to the virtual connection. Capacity calculation means for calculating based on information about traffic, connection control means for performing increase or decrease of the capacity of the virtual connection by signaling, a virtual connection determined to need capacity increase, and a request value for the increase. Request message including information for notifying the reconfiguration server of the reconfiguration server, and a reduction response including information for notifying the reconfiguration server of the virtual connection and the reduction response value whose capacity has been reduced by the connection control means. Each message Communication node, characterized in that a message generating means for generating. 3. A performance management means for relaying or terminating a virtual connection, collecting information on traffic and performance of the virtual connection and judging the necessity of capacity expansion, and determining a capacity to be allocated to the virtual connection. Capacity calculation means for calculating based on information about traffic, connection control means for performing the addition or reduction of the virtual connection capacity by signaling, and the virtual connection and the virtual connection which are determined to need capacity expansion via A reduction request message including information for notifying each communication node of each physical link to each communication node, and a reduction request message of a reduction response value which is a value whose capacity has been reduced by the connection control means. Communication Message generation means for respectively generating a reduction response message including information for notifying the node, and each of the terminated virtual connections specified in the reduction request message received from another node. Selecting means for selecting another virtual connection accommodated in the same physical link as the physical link, and receiving, from another node, a capacity expandable value of the virtual connection determined to need to be expanded. A communication node, which is determined based on a reduction response value and an expansion request value included in the reduction response message.