JP2007214796A - Atm network system, and obstacle excluding method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ATM network system capable of automatically excluding an obstacle to switching processing of an ATM switch. <P>SOLUTION: The ATM network system is equipped with a plurality of processors 1 which send cells 101 out, an ATM switch 2, and a controller 3 connected to the ATM switch 2. The ATM switch 2 has a plurality of ports 23 connected according to the plurality of processors 1, and switches cells 101 among the plurality of ports 23. The controller 3 disconnects a port 23 where a flow rate 106 of input cells 101 exceeds a prescribed reference flow rate 105 and a processor 1 corresponding to the port 23 from each other. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an ATM (Anchronous Transfer Mode) network system and a fault elimination method in an ATM network system, and more particularly to monitoring of a fault occurring in a processing device connected to an ATM switch and a fault elimination method.

  In an ATM (Asynchronous Transfer Mode) switch that accommodates a plurality of processing devices, a method of limiting the flow rate of cells sent from each processing device is employed in order to avoid congestion of cells sent into the network. ing. That is, the bandwidth set for each processing device is allocated to each port (communication channel), and the amount of cells exceeding this bandwidth is discarded or temporarily stored in a buffer based on the flow rate of the monitored cell. . For this reason, the ATM switch is provided with UPC (Usage Parameter Control) and NPC (Network Parameter Control) for monitoring the flow rate of cells sent from each processing device.

  However, when a failure occurs in a device (for example, an ATM cell generator circuit) related to generation or output of a cell of the processing device, the processing device may be in a state of continuously sending cells to the ATM switch. In such a case, since the restriction as described above cannot be applied to the processing apparatus that has failed, cells continue to flow into the ATM switch. This adversely affects the service of other processing devices connected to the ATM switch. For this reason, a large amount of cells that should not be received by other processing apparatuses continue to be received in large quantities, and the processing capability is reduced. Alternatively, since the ATM switch communication is compressed, the cell exchange processing capacity is reduced.

  In order to eliminate such a failure, it is necessary to physically disconnect the processing apparatus in which the failure has occurred from the ATM switch. However, in the conventional ATM network system, this disconnection is performed by a maintenance person. For this reason, it takes time to eliminate the failure, and the time during which the service quality deteriorates continues for a long time.

  As shown below, the prior art relating to fault monitoring and fault elimination in a network system is described.

  Japanese Patent Application Laid-Open No. 2005-236789 describes an ATM communication device that stops sending a cell from the cell transmission unit when the flow rate of the cell transmitted from the cell transmission unit is equal to or greater than a threshold (Patent Literature). 1). In the ATM communication device described in Patent Document 1, a cell transmission unit that sends a flow rate of a cell exceeding a threshold value is specified by a calculation process by a CPU. At this time, the CPU measures the flow rate of the cell and specifies the cell transmission unit based on the cell header obtained when the sent cell is buffered. For this reason, in the ATM communication apparatus described in Patent Document 1, when there are many data transmission units to be connected, the processing amount in the CPU increases, and there is a possibility that the time until cell transmission is stopped increases. When applied to an ATM network system using the ATM switch as described above, cells are not sent from the processing device in which the above failure has occurred, but the cells transmitted to the processing device are stopped. It is not possible.

  Japanese Patent Application Laid-Open No. 2001-339407 describes a LAN communication system in which a processing apparatus in which a failure has occurred is separated from the system to eliminate the failure (see Patent Document 2). The LAN communication system described in Patent Document 2 includes a processing device that is normally used and a spare processing device. In this system, when a failure occurs in a processing apparatus in use, the power supply of the processing apparatus is turned off and switched to a spare processing apparatus. However, in this system, an abnormality notification for notifying the occurrence of a failure is issued from the processing device. Therefore, when a failure occurs in which an abnormality notification cannot be issued, the processing device cannot be switched.

  Japanese Unexamined Patent Application Publication No. 2004-096460 describes an Ethernet switch that performs a duplex switching operation of a port when a transmission line failure occurs (see Patent Document 3). The Ethernet switch described in Patent Document 3 includes a first port connected to an operation link that is normally used and a second port connected to a backup link. When a failure occurs in the operation link, the first switch Stop using the port and switch to using the second link. However, with this switch, it is difficult to cope with a failure that causes a large amount of data to flow into the port.

Japanese Patent Laid-Open No. 07-202902 discloses a fault monitoring method for periodically executing fault monitoring of a module (processing device) connected to an ATM switch (see Patent Document 4).
JP 2005-236789 A JP 2001-339407 A JP 2004-096460 A Japanese Patent Laid-Open No. 07-202902

  An object of the present invention is to provide an ATM network system capable of automatically eliminating a failure that hinders an ATM switch replacement process.

  Another object of the present invention is to provide an ATM network system capable of eliminating a fault affecting other processing devices connected to the ATM switch.

  [Means for Solving the Problems] will be described below using the numbers and symbols used in [Best Mode for Carrying Out the Invention] in parentheses. This number / symbol is added to clarify the correspondence between the description of [Claims] and the description of the best mode for carrying out the invention. It should not be used for interpreting the technical scope of the invention described in [Scope].

An ATM network system according to the present invention includes a plurality of processing devices (1 ₁ to 1 ₃ , 1 ₁ ′ to 1 ₃ ′) for transmitting a cell (101), an ATM (Asynchronous Transfer Mode) switch (2, 2 ′), And a control device (3, 3 ′) connected to the ATM switch (2, 2 ′). The ATM switch (2, 2 ′) includes a plurality of ports (23 ₁ to 23 ₃ ) respectively connected to a plurality of processing devices (1 ₁ to 1 ₃ , 1 ₁ ′ to 1 ₃ ′). The cell (101) is switched between (23 ₁ to 23 ₃ ). The control device (3, 3 ′) includes a port (23) in which the flow rate (106) of the input cell (101) exceeds a predetermined reference flow rate (105), and a processing device (1) corresponding to the port (23). Disconnect the connection. As described above, a failure occurring in the processing device (1, 1 ′) can be monitored based on the flow rate of the cell (101) in the ATM switch (2, 2 ′). If the flow rate is abnormal, the faulty processing device (1, 1 ′) and the port (23) of the ATM switch (2, 2 ′) are disconnected, so that the faulty processing device (1, 1, 2) is disconnected. The output and input of the cell (101) to the port (2, 2 ') to which') connects can be stopped.

The ATM switch (2, 2 ′) preferably includes a plurality of flow rate determination units (21 _{1 to} 21 ₃ ) connected to the plurality of ports (23 ₁ to 23 ₃ ), respectively. Each of the plurality of flow rate determination units (21 _{1 to} 21 ₃ ) measures the flow rate of the cell (101) input to each of the corresponding plurality of ports (23 ₁ to 23 ₃ ), and the measured flow rate (106) When the predetermined reference flow rate (105) is exceeded, a failure notification signal (104) is issued to the control device (3, 3 ′). In response to the failure notification signal (104), the control device (3, 3 ') has a port (23) in which the measured flow rate (106) exceeds the reference flow rate (105), and a processing device (1) corresponding to this port (23). 1 ′) is disconnected. As described above, according to the present invention, since the failure determination unit (21) that measures the flow rate of the cell (101) for each port (23) and executes failure determination is provided, the processing apparatus ( 1, 1 ′) can be quickly identified and the separation of the processing device (1, 1 ′) can be controlled independently of each other.

  According to the ATM network system according to the first aspect, in the control device (3), the flow rate of the cell (101) input from the processing device (1) to the port (23) exceeds the predetermined reference flow rate (105). In this case, a power stop signal (103) is issued to the processing device (1). The processor (1) stops supplying power to itself in response to the power stop signal (103). The processing device (1) to which power is not supplied cannot transfer the cell (101) to the ATM switch (2). For this reason, the flow of abnormal cells to the ATM switch (1) can be stopped, and troubles that affect communication services performed by other processing devices (1) and exchange processing in the ATM switch (2) are eliminated. can do.

Further, a failure notification bus (4) provided between the plurality of flow rate determination units (21 _{1 to} 21 ₃ ) and the control unit (3), the control device (3), and the plurality of processing devices (1 ₁ to 1). ₃ ) and a power supply control bus (5) provided between them. The flow rate determination unit (21) that has determined that the measured flow rate (106) of the cell (101) input from the processing device (1) exceeds the reference flow rate (106) is controlled by the control unit via the fault notification bus (4). The failure notification signal (104) is issued to (3). Based on the failure notification signal (104), the control device (3) issues a power stop signal (103) to the processing device (1) via the power control bus (5). According to the present invention, the failure notification bus (4) and the power supply control bus (5) are provided independently for the communication lines, so that the failure monitoring and power supply can be performed without being affected by the communication communication status between the processing devices. Can be controlled.

  According to the ATM network system of the second aspect, the control device (3 ′) is configured such that the flow rate (106) of the cell (101) input from the processing device (1 ′) to the port (23) is a predetermined reference flow rate. If (105) is exceeded, a use port control signal (107) is issued to the ATM switch (2 '). The ATM switch (2 ') stops the use of the port (23) based on the use port control signal (107). By not using the port (23) connected to the processing device (1 ′) where the failure has occurred in this way, it is possible to prevent the inflow of the cell (101) transmitted from the processing device (1 ′) that is the failure target. it can.

Further, a failure notification bus (4) provided between the plurality of flow rate determination units (21 _{1 to} 21 ₃ ) and the control unit (3 ′), the control device (3 ′), and the plurality of processing devices (1 _1). It is preferable to further comprise a switch control bus (5 ′) provided between “˜1 ₃ ′). The flow rate determination unit (21) that has determined that the measured flow rate (106) exceeds the reference flow rate (105) issues a failure notification signal (104) to the control unit (3 ′) via the failure notification bus (4). . In response to the failure notification signal (104), the control device (3 ′) issues a use port control signal (107) to the ATM switch (2 ′) via the switch control bus (5 ′). According to the present invention, the failure notification bus (4) and the switch control bus (5 ') are provided independently for the communication lines, respectively, so that the failure monitoring and monitoring can be performed without being affected by the communication status between the processing devices. Power supply can be controlled.

  As described above, according to the ATM network system of the present invention, the processing device (1, 1 ′) that has failed is stopped by the other processing device via the ATM switch (2, 2 ′). May have adverse effects. By automatically suppressing this influence, the service stop time can be shortened as much as possible. In addition, it is possible to prevent that one processing apparatus (1) becomes an obstacle and the service quality of the other processing apparatus (1) is deteriorated due to the influence.

  The ATM network system according to the present invention can automatically eliminate a failure that hinders an ATM switch replacement process.

  In addition, it is possible to eliminate a failure that affects other processing devices connected to the ATM switch.

  Hereinafter, an embodiment of an ATM network system according to the present invention will be described with reference to the accompanying drawings. In the drawings, the same or similar reference numerals indicate the same, similar, or equivalent components. In addition, when there are a plurality of configurations of the same code, a subscript is added to the code and the configuration is generically indicated by a code without a subscript.

(First embodiment)
A first embodiment of an ATM network system according to the present invention will be described below with reference to FIGS.
(Configuration of ATM network system in the first embodiment)
The configuration of the ATM network system according to the first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing the configuration of the ATM network system according to the first embodiment of the present invention. The ATM network system according to the present invention includes a plurality of processing devices 1 ₁ to 1 ₃ , an ATM switch 2, and a control device 3. ATM switch 2 is connected to a plurality of processing devices ₁ 1 to 1 _3, it executes the exchange process of the data transmitted between the plurality of processing devices ₁ 1 to 1 _3. The ATM network system includes a failure notification bus 4 connected to the control device 3 and a power supply control bus 5. Processing apparatus 1 ₁ to 1 ₃ are connected to the controller 3 via the bus 4 and a power control bus for fault notification. The ATM switch 2 is connected to the control device 3 through a failure notification bus 4. The control device 3 is a computer device that controls the power supply of the processing device 1 in response to failure notification signals 104 and 104 ′ notified via the failure notification bus 4.

ATM switch 2 is connected to a plurality of flow rate determining unit ₂₁ 1 to 21 ₃ which are connected in correspondence with the respective processing apparatus ₁ 1 to 1 _3, in correspondence with the respective flow rates determining unit ₂₁ 1 to 21 ₃ A plurality of ports 23 ₁ to 23 ₃ and a switch unit 22 for performing an exchange process of the ATM cell 101 between the ports 23 are provided. Here, the number of processing devices 1 connected to the ATM switch 2 is not limited to three, and the number of ports 23 and the number of flow rate determination units 21 included in the ATM switch 2 are not limited to this. Each of the plurality of ports 23 ₁ to 23 ₃ is associated with a line number exemplified by a virtual channel identifier and a virtual path identifier. The switch unit 22 performs switching in accordance with the destination line number included in the header of the ATM cell 101 transmitted from the processing device 1 and transfers it to the processing device 1 connected to the port 23 corresponding to the line number. The processing device 1 is a computer device that includes a CPU and a memory. Each of the processing devices 1 ₁ to 1 ₃ is connected to the corresponding port 23 in which the line numbers of the connection destination ports 23 ₁ to 23 ₃ are set. For example, the processor _{1 1} is connected to port 23 ₁ corresponding to the header of the line number "000".

  FIG. 2 is a block diagram illustrating configurations of the processing apparatus 1 and the flow rate determination unit 21. Referring to FIG. 2, processing device 1 includes a power supply control unit 11, a power supply 12, an ATM generation unit, and an ATM cell transmission / reception unit. The ATM cell generation unit 13 includes a CPU and a memory (not shown), and generates an ATM cell 101 from data to be transferred to another processing device. The ATM cell generation unit 13 divides the data to be transferred to the other processing device 1 into fixed-length data, adds a header including the destination line number, and generates the ATM cell 101. The ATM cell transmission / reception unit 14 is connected to the ATM switch 2 to control transmission / reception of the ATM cell 101.

  Here, the ATM cell generation unit 13 and the ATM transmission / reception unit 14 are operated by the power supplied from the power supply 12. In response to the power control signal 103 issued by the power control unit 11, the power source 12 determines on / off of power supplied to the ATM cell generation unit 13 and the ATM transmission / reception unit 14. The power supply control unit 11 decodes a command issued via the power supply control bus 5 and issues a power supply control signal 103 to the power supply 12. In addition, a power control signal 103 for stopping the power supply 12 is issued in response to the power supply stop signal 102 transmitted from the control device 3.

  The control device 3 monitors a failure occurring in each processing device 1 and the ATM switch 2 by the failure notification signals 104 and 104 ′ notified from each processing device 1 and the ATM switch 2 via the failure notification bus 4. A computer device. The control device 3 controls the power supply of the processing device by issuing a power supply stop signal 102 via the power supply control bus 5 using the failure notification signals 104 and 104 'as a trigger. Here, the failure notification signal 104 includes an identifier (for example, a line number) for identifying the processing device 1 in which the failure has occurred. The control device 3 identifies the processing device 1 in which a failure has occurred based on the identifier included in the failure notification signal 104. In addition, a power stop signal 102 is sent to the power control bus 5 to the specified processing apparatus 1.

  The failure notification signals 104 and 104 ′ issued from the ATM switch 2 may include, as failure information, a failure content identifier corresponding to the type of failure and information indicating the failure scale. For example, the failure notification signal 104 may include a measured value (flow rate measured value 106) of the ATM cell 101 input to each port 23 of the switch unit 22. In this case, the control unit 3 further includes a device for displaying or notifying the failure processing device and the content of the failure based on the failure information included in the failure notification signal 104 and the identifier of the processing device in which the failure has occurred. It is preferable. The control unit 3 notifies the failure information included in the failure notification signal 104 by voice or character data, so that the supervisor can grasp the failure processing apparatus separated for failure elimination and the content of the failure.

  The ATM switch 2 includes a flow rate determination unit 21 that is connected to each port 23 and measures the flow rate of the ATM cell 101 that is input to the port 23 to be connected. With reference to FIG. 2, the flow rate determination unit 23 includes a flow rate measurement unit 211, a reference value storage unit 212, and a comparison unit 212. The flow rate measuring unit 211 includes a timer for notifying a certain time and a counter for counting the number of headers of the ATM cell 101 input to the connected port 23. The counter counts the total number of headers input during a certain time. The flow rate measurement unit 211 notifies the comparison unit 213 of the total number of headers counted by the counter as the flow rate measurement value 106 of the ATM cell 101 at regular time intervals notified from the timer. The reference value storage unit 212 is a storage device that stores a flow rate reference value 105 used for failure determination. The flow rate reference value 105 is, for example, a failure determination threshold value set based on the flow rate of the ATM cell 101 that prescribes band control and path control. Specifically, a value obtained by adding a threshold value that is regarded as a failure to the transmission amount that defines the bandwidth control is set as the flow rate reference value 105. The flow rate reference value 105 may be set to a different value for each port 23 or the same value. The setting method of the flow rate reference value 105 may be set in advance by a maintenance person of the ATM network system or may be set based on a setting value reported from the processing device 1 connected to the ATM switch 2 in communication. good.

  The comparison unit 213 compares the flow rate measurement value 106 and the flow rate reference value 105 to determine whether or not there is a failure in the processing apparatus 1 connected to the port 23. If it is determined that the flow rate is abnormal, a failure notification signal 104 to which the line number of the port is added is transmitted to the control unit 3. At this time, the measured flow rate 106 may be included in the failure notification signal 104. Specifically, the comparison unit 213 compares the magnitude of the flow rate measurement value 106 with the flow rate reference value 105, and if the flow rate measurement value 106 is greater than the flow rate reference value 105, the failure with the line number of the corresponding port added A notification circuit that transmits the notification signal 104 to the control unit 3. The determination process in the comparison unit 213 may be performed by a calculation process by a CPU (not shown) provided in the ATM switch 2. In this case, it is preferable that the flow rate reference value 106 is associated with each port 23 and stored in a storage device (not shown). In response to the flow rate measurement value 106 transmitted from the flow rate determination unit 211 of each port 23, the CPU extracts the flow rate reference value 23 corresponding to the port 23 from the storage device, and performs a comparison process.

(Operation)
With reference to FIG. 1 and FIG. 2, a fault elimination operation in the first embodiment of the ATM network system according to the present invention will be described.

Each ATM cell reception section 14 of the processing device ₁ 1 to 1 ₃ connected to the ATM switch 2, declare delivery rate of the ATM cells 101 (e.g., transmission quantity defining a bandwidth control) in the ATM switch 2. The ATM switch 2 calculates a flow rate reference value 105 by adding a predetermined threshold to the reported transmission amount, and stores it in the reference value storage unit 212 corresponding to the transmission source line number. Note that the processing device 1 may transmit the flow rate reference value 105 together with the ATM cell 101 sending amount declaration. In this case, the ATM switch 2 directly stores the transmitted flow rate reference value 105 in the corresponding reference value storage unit 212. When the flow rate reference value 105 is set, the processing apparatus 1 enters an operating state and starts transmission / reception of the ATM cell 101. Further, the ATM switch 2 performs band control and path control by performing discard processing of the ATM cell 101 or transfer processing by smoothing by UPC or NPC (not shown) based on the transmission amount of the ATM cell 101 declared from the processing device 1. Execute.

Here, a failure elimination method when a failure that can notify the occurrence of a failure has occurred in the processing apparatus 1 will be described. Faults that can be notified include, for example, a bus and a data path in the processing device 1, a parity error in the ATM cell generation unit 13, a pilot pattern error, a clock loss, and the like. If such failure occurs while the processor 1 ₁ to 1 ₃ is operated, the processing apparatus 1 fails notifies the failure to the controller 3 via the fault notification bus 4. The processing device 1 transmits a failure notification signal 104 ′ including its own identification number and failure content to the control device 3. The control device 3 displays the name of the processing device in which the failure has occurred and the content of the failure based on the information included in the failure notification signal 104 ′. Further, referring to the contents of the failure, it is determined whether it is necessary to disconnect the processing apparatus in which the failure has occurred. When it is necessary to disconnect, the control device 3 issues a power supply stop signal 102 to the processing device 1 where the failure has occurred via the power supply control bus 5. The power supply control unit 11 of the processing apparatus 1 that has received the power supply stop signal 102 outputs the power supply control signal 103 to the power supply 12 to stop the power supply 12. Note that, in order to determine whether or not it is necessary to disconnect the processing device according to the failure content, the control device 3 holds a table in which the failure content is associated with a failure elimination method (for example, power-off of the processing device 1). It is preferable.

Next, a failure elimination method in the case where a failure that cannot be notified of the occurrence of a failure occurs in the processing device 1 will be described. In this embodiment, the ATM cell generator 13 of the processing device 1 ₁ failure is described as being generated. In the processing apparatus _{1 1} that is in the operational state, the ATM cell generator 13 malfunctions, it may become in a state of continuing to transmit the ATM cells 101 at the full rate. If such a failure occurs, typically, processor 1 ₁ is not aware that a failure has occurred, does not transmit a fault notification signal 104 'to the control unit 3. Further, when an abnormal amount of ATM cells 101 flows into the ATM switch 2, the exchange processing capacity is lowered, and the communication service for the other processing devices 1 ₂ and 1 ₃ is adversely affected.

On the other hand, the flow rate determination unit 21 ₁ monitors the flow rate of the ATM cell 101 input from the processing device 1 ₁ to the port 23 ₁ . Flow measuring portion 211 of the flow rate determining unit 21 ₁ outputs to the comparator 213 the number of ATM cells every predetermined time interval as the flow rate measurement value 106. When acquiring the flow rate measurement value 106, the comparison unit 213 acquires the flow rate reference value 105 from the reference value storage unit 212 and compares it. When the flow rate measurement value 106 is smaller than the flow rate reference value 105, it is determined that there is no failure and the ATM flow rate is continuously monitored. However, when the flow rate measurement value 106 is greater than the flow rate reference value 105, it determines that failure has occurred in the target processing device 1 _1, issues a fault notification signal 104. That is, when the above-described failure occurs in the ATM cell generation unit 13, the ATM switch 2 can automatically execute failure determination and failure notification.

When the comparison unit 213 detects a failure, the comparison unit 213 transmits a failure notification signal 104 including the line number to be monitored and the flow rate measurement value 106 to the control device 3 via the failure notification bus 4. The control device 3 identifies a processing device corresponding to the line number included in the transmitted failure notification signal 104. At this time, it is preferable that the control device 3 holds a table in which a line number and an identifier for specifying a processing device are associated with each other. The controller 3 issues a power down signal 102 to the processor 1 ₁ identified. Power control unit 11 of the processing apparatus 1 ₁ that the power stop signal 102 received by issuing a power control signal 103 to the power supply 12 to stop supplying power from the power supply 12 to the ATM cell generator 13. The ATM switch 2 ′ preferably notifies the other processing devices 1 ₂ ′ and 1 ₃ ′ that the communication addressed to the port 23 ₁ has been cut off. At this time, the processing devices 1 ₂ ′ and 1 ₃ ′ having received the notification stop the transmission of the ATM cell 101 addressed to the processing device 1 ₁ ′.

The control as described above, illegal ATM cells from the processing unit 1 ₁ is no longer sent, sending other services and the processing device 1 ₂ and 1 ₃ which has inhibited the communication by abnormal ATM cells, ATM switch 2 The exchange processing service can be improved.

  The ATM network system according to the present invention can identify a fault processing device and automatically disconnect the processing device 1 from the system even when a fault that occurs in the processing device 1 and cannot be notified by the processing device 1 occurs. . Further, since the failure notification bus 4 and the power control bus 5 are provided independently, failure notification and power control can be executed without being affected by the communication communication state between the processing devices 1.

(Second Embodiment)
Hereinafter, a second embodiment of the ATM network system according to the present invention will be described with reference to FIGS. The configuration with the same reference numerals as in the first embodiment is the same in operation and function, and therefore description thereof is omitted.

(Configuration of ATM network system in the second embodiment)
The configuration of the ATM network system according to the second embodiment of the present invention will be described with reference to FIG. FIG. 3 is a block diagram showing the configuration of the ATM network system according to the third embodiment of the present invention. The ATM network system according to the present invention includes a plurality of processing devices 1 ₁ ′ to 1 ₃ ′, an ATM switch 2 ′, and a control device 3 ′. The processing devices 1 ₁ ′ to 1 ₃ ′ and the control device 3 ′ are connected by a failure notification bus 4. Further, the ATM switch 2 'and the control device 3' are connected by a failure notification bus 4 and a switch control bus 5 '. In the ATM network system according to the second embodiment, the opening and closing of the port 23 of the ATM switch 2 ′ connected to the processing device 1 ′ subject to failure is controlled so that the processing device 1 ′ serving as the failure target is connected to the ATM switch 2 ′. Separate.

  The ATM switch 2 'is configured to include a switch unit 22' connected to the switch control bus 5 'in place of the switch unit 22 of the ATM switch 2 in the first embodiment. The switch unit 22 ′ switches according to the destination line number included in the header of the ATM cell 101 transmitted from the processing device 1 ′ and transfers it to the processing device 1 connected to the port 23 corresponding to the line number. Further, in response to the use port control signal 107 output from the control device 3 ′ via the switch control bus 5 ′, the port 23 to be failed is closed and input / output to the port 23 is stopped.

The processing device 1 ′ is a computer device that includes the ATM cell generation unit 13 and the ATM cell transmission / reception unit 14 and does not include the power supply control unit 11 in the first embodiment. Each of the processing devices 1 ₁ ′ to 1 ₃ ′ is connected to the corresponding port 23 in which the line numbers of the connection destination ports 23 ₁ to 23 ₃ are set. For example, the processing device 1 ₁ ′ is connected to the port 23 ₁ corresponding to the line number “000” in the header.

  The control unit 3 ′ is generated in each processing device 1 ′ and ATM switch 2 ′ by the failure notification signals 104 and 104 ′ notified from each processing device 1 ′ and the ATM switch 2 ′ via the failure notification bus 4. It is a computer device that monitors failures that occur. The control device 3 ′ uses the failure notification signal 104 as a trigger to issue a use port control signal 107 via the switch control bus 5 ′ and controls the use of the port 23 in the switch unit 22 ′. Here, the failure notification signal 104 includes the line number of the port connected to the processing device 1 ′ where the failure has occurred. The control device 3 identifies the port 23 where the failure has occurred based on the line number included in the failure notification signal 104.

(Operation)
With reference to FIG. 3 and FIG. 4, the fault elimination operation in the second embodiment of the ATM network system according to the present invention will be described.
The ATM cell transmitting / receiving unit 14 of each of the processing devices 1 ₁ ′ to 1 ₃ ′ connected to the ATM switch 2 ′ declares the transmission amount of the ATM cell 101 (for example, the transmission amount that defines the bandwidth control) to the ATM switch 2 ′. To do. The ATM switch 2 ′ calculates a flow rate reference value 105 by adding a predetermined threshold to the reported transmission amount, and stores it in the reference value storage unit 212 corresponding to the transmission source line number. Note that the processing device 1 ′ may transmit the flow rate reference value 105 ′ together with the ATM cell 101 sending amount declaration. In this case, the ATM switch 2 ′ directly stores the transmitted flow rate reference value 105 ′ in the corresponding reference value storage unit 212. When the flow rate reference value 105 is set, the processing apparatus 1 ′ enters an operating state and starts transmission / reception of the ATM cell 101. Further, the ATM switch 2 ′ performs band control and path control by performing transfer processing by discarding or smoothing of the ATM cell 101 based on the transmission amount of the ATM cell 101 declared from the processing device 1 ′.

Here, a failure elimination method in the case where a failure that cannot be notified of the occurrence of a failure occurs in the processing device 1 ′ will be described. In the present embodiment, a case where a failure occurs in the ATM cell generation unit 13 of the processing device 1 ₁ ′ will be described. In the processing device 1 ₁ ′ in the operational state, the ATM cell generation unit 13 may be in a state of continuing to transmit a large amount of ATM cells 101. When such a failure occurs, the processing device 1 ₁ ′ usually does not recognize that the failure has occurred and cannot notify the control device 3 of the failure.

On the other hand, the flow rate determination unit 21 ₁ monitors the flow rate of the ATM cell 101 input from the processing device 1 ₁ ′ to the port 23 ₁ . Flow rate determining unit 21 _1, when the flow rate measurement value 106 is greater than the flow rate reference value 105, and determines that a failure has occurred in the target processing device 1 _1, issues a fault notification signal 104. When the comparison unit 213 detects a failure, the comparison unit 213 transmits a failure notification signal 104 including the line number to be monitored and the flow rate measurement value 106 to the control device 3 via the failure notification bus 4. The control device 3 specifies the port 23 corresponding to the line number included in the transmitted failure notification signal 104. The controller 3 issues a use port control signal 107 to close the port 23 ₁ identified. Switching unit 22 having received the used port control signal 107 'closes the switch circuits leading to the port 23 ₁ specified by using the port control signal 107. The ATM switch 2 ′ preferably notifies the other processing devices 1 ₂ ′ and 1 ₃ ′ that the communication addressed to the port 23 ₁ has been cut off. At this time, the processing devices 1 ₂ ′ and 1 ₃ ′ having received the notification stop the transmission of the ATM cell 101 addressed to the processing device 1 ₁ ′.

By the control as described above, there is no illegal ATM cell input from the processing device 1 ₁ ′ to the ATM switch 2 ′, and the other processing devices 1 ₂ ′ and 1 whose communication is hindered by sending out abnormal ATM cells. It is possible to improve the ₃ ′ service and the exchange processing service in the ATM switch 2 ′.

  The ATM network system according to the second embodiment can specify a port connected to the failure processing device even when a failure occurs in the processing device 1 ′ and cannot be notified by the processing device 1 ′. The processing device 1 ′ can be disconnected from the system. Further, since the failure notification bus 4 and the switch control bus 5 'are provided independently, failure notification and port control can be executed without being affected by the communication communication state between the processing devices 1'.

  As mentioned above, according to the ATM network system by this invention, since the flow volume determination part 23 is provided for every port, the failure determination for every processing apparatus connected to a port can be performed in a very short time. In addition, since the failure of the processing device is detected based on the ATM flow rate in the ATM switch and the processing device subject to the failure is separated, the processing device that cannot determine the failure state and the processing device that cannot notify the occurrence of the failure are excluded. be able to.

  The embodiment of the present invention has been described in detail above, but the specific configuration is not limited to the above-described embodiment, and changes within a scope not departing from the gist of the present invention are included in the present invention. . The control device in the present embodiment is provided outside the ATM switch, but may be provided in the ATM switch.

FIG. 1 is a configuration diagram of an ATM network system according to a first embodiment of the present invention. FIG. 2 is a block diagram showing a signal flow in the first embodiment of the ATM network system according to the present invention. FIG. 3 is a configuration diagram of the ATM network system according to the second embodiment of the present invention. FIG. 4 is a block diagram showing a signal flow in the second embodiment of the ATM network system according to the present invention.

Explanation of symbols

1, 1 ₁ to 1 ₃ , 1, 1 ₁ ′ to 1 ₃ ′: Processing device 2, 2 ′: ATM switch 3, 3 ′: Control device 4: Fault notification bus 5: Power supply control bus 5 ′: Switch Control bus 11: Power supply control unit 12: Power supply 13: ATM cell generation unit 14: ATM cell transmission / reception unit 21, 21 _{1 to} 21 ₃ : Flow rate determination unit 22, 22 ′: Switch unit 23, 23 ₁ to 23 ₃ : Port 211: Flow rate determination unit 212: Reference value storage unit 213: Comparison unit 101: ATM cell 102: Power supply stop signal 103: Power supply control signal 104, 104 ′: Failure notification signal 105: Flow rate reference value 106: Flow rate measurement value 107: Use Port control signal

Claims (9)

A plurality of processing devices for sending cells;
An ATM (Asynchronous Transfer Mode) switch that includes a plurality of ports respectively connected to the plurality of processing devices, and performs switching of the cell between the plurality of ports;
A control device connected to the ATM switch,
The control device disconnects a connection between a port in which a flow rate of an input cell exceeds a predetermined reference flow rate and a processing device corresponding to the port. ATM network system. The ATM network system according to claim 1,
The ATM switch includes a plurality of flow rate determination units respectively connected to the plurality of ports.
Each of the plurality of flow rate determination units measures the flow rate of a cell input to each of the corresponding plurality of ports, and issues a failure notification signal to the control device when the measured flow rate exceeds a predetermined reference flow rate. And
The control device disconnects the connection between the port whose measured flow rate exceeds the reference flow rate and the processing device corresponding to the port in response to the failure notification signal. In the ATM network system according to claim 1 or 2,
When the flow rate of the cell input from the processing device to the port exceeds a predetermined reference flow rate, the control device issues a power stop signal to the processing device,
The processing device stops supplying power to itself in response to the power stop signal. In the ATM network system according to claim 1 or 2,
When the flow rate of the cell input to the port from the processing device exceeds a predetermined reference flow rate, the control device issues a use port control signal to the ATM switch,
The ATM switch stops use of the port based on the use port control signal. The ATM network system according to claim 3,
A failure notification bus provided between the plurality of flow rate determination units and the control unit;
A power control bus provided between the control device and the plurality of processing devices;
The flow rate determination unit that determines that the measured flow rate of the cell input from the processing device exceeds the reference flow rate, issues the failure notification signal to the control unit via the failure notification bus,
The said control apparatus issues the said power supply stop signal with respect to the said processing apparatus via the said control bus for power supplies based on the said failure notification signal. ATM network system. The ATM network system according to claim 4,
A failure notification bus provided between the plurality of flow rate determination units and the control unit;
A switch control bus provided between the control device and the plurality of processing devices;
The flow rate determination unit that determines that the measured flow rate exceeds the reference flow rate issues the failure notification signal to the control unit via the failure notification bus,
The said control apparatus issues the said use port control signal with respect to the said ATM switch via the said bus for switch control in response to the said failure notification signal. ATM network system. In an ATM (Asynchronous Transfer Mode) switch that performs cell switching between a plurality of ports connected to a plurality of processing devices, a step of measuring a flow rate of a cell input to each of the plurality of ports;
A failure elimination method comprising: a port at which the measured flow rate exceeds a predetermined reference flow rate, and a step of disconnecting a connection with a processing device corresponding to the port. The failure elimination method according to claim 7,
Issuing a power stop signal to a processing device connected to a port where the flow rate exceeds a predetermined reference flow rate;
A failure elimination method comprising: a step of stopping the supply of power to itself in response to the power stop signal. The failure elimination method according to claim 7,
Issuing a use port control signal to the ATM switch if the flow rate exceeds a predetermined reference flow rate;
The ATM switch comprises a step of stopping use of a port whose flow rate exceeds a predetermined threshold in response to the use port control signal.

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