JP3989812B2 - Communication system and method for changing port state of spanning tree bridge device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is a communication system comprising at least two spanning tree bridge devices connected to two transmission paths, one of which is used as an active transmission path and the other as a backup transmission path, and is used in this communication system. The spanning tree bridge device and the spanning tree bridge device port state changing method, in particular, one of the spanning tree bridge devices determines the transmission path to be used when a failure occurs in the active transmission path. The present invention relates to a communication system including means for changing from a standby transmission path to a standby transmission path, a spanning tree bridge device used in the communication system, and a port state changing method of the spanning tree bridge device.
[0002]
[Prior art]
When connecting a plurality of bridge devices through a plurality of transmission paths, a spanning tree protocol is implemented in each bridge device. The spanning tree protocol is a protocol for using only one transmission path as the active transmission path and multiple other transmission paths as backup transmission paths when there are multiple transmission paths connecting multiple bridge devices. is there. In the following description, a bridge device in which the spanning tree protocol is implemented is called a spanning tree bridge device. Each spanning tree bridge device has a port connected to each transmission path, and a frame called a configuration BPDU (hereinafter simply referred to as a BPDU) is transmitted and received from this port. This BPDU is a broadcast frame between the spanning tree bridge devices, and all the spanning tree bridge devices connected to the same transmission path transmit and receive this frame. Each spanning tree bridge device determines the state of each port in its own device based on the content of the received BPDU, and further transmits the BPDU from the designated port in its own device.
[0003]
Conventionally, in a spanning tree bridge device, each port in its own device has a timer called a message age timer, and a root port and a blocking port (also called a closed port) use the respective timers for BPDUs. Monitor. If the BPDU is not confirmed for a predetermined period, the timer times out. When the above-mentioned timeout occurs in the port connected to the working transmission path, the spanning tree bridge device is connected to the working transmission path in order to change the transmission path to be used to the standby transmission path. Is changed from the root port to the closed port, and the state of the port connected to the backup transmission path is changed from the closed port to the root port. By executing such change processing, the port connected to the standby transmission path in the spanning tree bridge device becomes ready for transmission and reception, and the transmission path to be used is changed from the active transmission path to the standby transmission path. (For example, refer to Patent Document 1).
[0004]
[Patent Document 1]
JP-A-6-350606
[0005]
[Problems to be solved by the invention]
However, in the prior art, the timeout setting time set for each port of the spanning tree bridge device to be determined as a timeout is normally 20 seconds, so the ports connected to the working transmission path It takes 20 seconds at the maximum to be recognized as a time-out, and it takes time to change from the active transmission path to the standby transmission path. For this reason, when a failure occurs in the active transmission path, it has been desired to shorten the time required to change the transmission path to be used to the standby transmission path.
[0006]
[Means for Solving the Problems]
  Therefore, the communication system of the present invention solves the above-described problems with the following characteristic configuration.
[0007]
That is, the communication system of the present invention has a first spanning tree bridge device that has a first port and a second port, changes the state of each port according to the spanning tree protocol, and outputs a BPDU from the first port. And a first transmission path connected to the first port;A transmission device provided in the first transmission path;A second transmission path connected to the second port, a third port connected to the other end of the first transmission path, and a fourth port connected to the other end of the second transmission path; A communication system comprising a second spanning tree bridge device for changing the states of the third and fourth ports according to a spanning tree protocol,The transmission apparatus monitors a control signal transmitted from the first spanning tree bridge apparatus, and detects a link break when the control signal is not detected for a predetermined period shorter than the BPDU transmission interval. Means for stopping signal output to the second spanning tree bridge device when detectingThe second spanning tree bridge device is:From transmission equipmentMonitor the received signal to the third portFaithIssuePredetermined shorter than BPDU transmission intervalA link break detection means for outputting a link break detection signal when no period is detected;,NCut offDetection signalIssuePort setting changing means for changing the third port to a closed port and changing the fourth port to a root port when input is provided.
[0008]
Furthermore, the communication system of the present invention has a first spanning tree bridge device that has a first port and a second port, changes the state of each port according to a spanning tree protocol, and outputs a BPDU from the first port. A first transmission path connected to the first port; a first transmission device and a second transmission device included in the first transmission path; a second transmission path connected to the second port; It has a third port connected to the other end of the first transmission path and a fourth port connected to the other end of the second transmission path, and changes the state of the third and fourth ports according to the spanning tree protocol. A communication system including a second spanning tree bridge device, wherein the first transmission device transmits a control signal transmitted from the first spanning tree bridge device. And when the control signal is not detected for a predetermined period shorter than the transmission interval of the BPDU, means for detecting a link break and stopping the signal output to the second transmission device when the link break is detected. The second transmission device monitors a control signal transmitted from the first transmission device, detects a link break if the control signal is not detected for a predetermined period shorter than the transmission interval of the BPDU, and Means for stopping signal output to the second spanning tree bridge device when link breakage is detected, and monitoring a received signal from the first transmission device and detecting the received signal for a predetermined period shorter than the transmission interval of the BPDU If not, a means for detecting a link break and stopping the signal output to the second spanning tree bridge device when the link break is detected is provided. The bridge device monitors link signals from the second transmission device to the third port, and outputs a link break detection signal when the received signals are not detected for a predetermined period shorter than the BPDU transmission interval. And a port setting changing unit that changes the third port to a closed port and changes the fourth port to a root port when a link disconnection detection signal is input.
[0009]
  In addition, the port state changing method for the spanning tree bridge device of the present invention solves the above-described problems by the following characteristic method.
[0010]
That is, the port state changing method of the present invention includes a third port connected to a first spanning tree bridge device that outputs a BPDU through a first transmission path that is set as a root port and includes a transmission device, and a closed port. And a fourth port connected to the first spanning tree bridge device via the second transmission path, wherein the transmission device uses the first spanning method in the port state changing method of the second spanning tree bridge device. Monitoring a control signal transmitted from the tree bridge device, detecting a link disconnection when the control signal is not detected for a predetermined period shorter than the BPDU transmission interval, and detecting the link disconnection A step of stopping signal output to the second spanning tree bridge device; A step in which the device monitors a received signal from the transmission device to the third port, a step in which the received signal is not detected for a predetermined period shorter than the transmission interval of the BPDU, and a detection of the broken link And changing the third port to a closed port and changing the fourth port to a root port.
[0011]
Furthermore, the port state changing method of the present invention is connected to a first spanning tree bridge device that outputs a BPDU via a first transmission path that is set as a root port and includes a first transmission device and a second transmission device. Port state changing method for a second spanning tree bridge device having a third port configured as a closed port and a fourth port set as a closed port and connected to the first spanning tree bridge device via a second transmission path The first transmission device monitors the control signal transmitted from the first spanning tree bridge device, and detects that the link is disconnected when the control signal is not detected for a predetermined period shorter than the BPDU transmission interval. A step of stopping signal output to the second transmission device when the link disconnection is detected, and a second transmission device Monitoring the received signal from the first transmission device, detecting the link break if the received signal is not detected for a predetermined period shorter than the BPDU transmission interval, and detecting the link break A step of stopping signal output to the second spanning tree bridge device, a step of the second spanning tree device monitoring a reception signal from the second transmission device to the third port, and the reception signal of the BPDU A step of detecting a link break when no predetermined period shorter than the transmission interval is detected, and a step of changing the third port to a closed port and changing the fourth port to a root port when the link break is detected.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings, but the present invention is not limited to the following embodiments.
[0013]
(Embodiment 1)
In the first embodiment, the present invention is applied to an EPON (Ethernet (registered trademark) Passive Optical Network) system which is one of subscriber access systems. FIG. 1 is a configuration diagram of an EPON system according to the first embodiment. In FIG. 1, an EPON system 1 includes a spanning tree bridge device 2. The spanning tree bridge device 2 is a device that functions as a root bridge in the spanning tree protocol, and includes a port 2a and a port 2b. Port 2a is set as a designated port (Designated Port) in the spanning tree protocol as an initial setting, and port 2b is set as a closed port (Blocked Port). The spanning tree bridge device 2 has a function of determining the states of the ports 2a and 2b according to the spanning tree protocol.
[0014]
The intra-station subscriber accommodation device LT1 is connected to the port 2a of the spanning tree bridge device 2 via the cable 3. A star coupler SC1 is connected to the in-station subscriber accommodation apparatus LT1 through an optical fiber 4. .., NT1n are connected to the star coupler SC1 via a plurality of optical fibers 51,..., 5n. The intra-station subscriber accommodation device LT2 is connected to the port 2b of the spanning tree bridge device 2 via the cable 6. A star coupler SC2 is connected to the in-station subscriber accommodation apparatus LT2 via an optical fiber 7. .., NT2n are connected to the star coupler SC2 via a plurality of optical fibers 81,..., 8n.
[0015]
Spanning tree bridge device 11 is connected to home subscriber termination devices NT11 and NT21 via cables 9 and 10. The spanning tree bridge device 11 has a port 11 a connected to the cable 9 and a port 11 b connected to the cable 10. In the first embodiment, the port 11a is set as a root port in the spanning tree protocol, and the port 11b is set as a closed port. Spanning tree bridge devices (not shown) for the home subscriber termination devices NT1i (i = 2,..., N) and NT2i (i = 2,..., N) as well as the home subscriber termination devices NT11 and NT21. Is connected. In the EPON system 1, the in-house subscriber terminators NT11,..., NT1n connected via the in-house subscriber accommodation device LT1, the optical fiber 4 and the star coupler SC1 are used as the working transmission path, and the in-office subscriber accommodation is accommodated. .., NT2n connected via the device LT2, the optical fiber 7 and the star coupler SC2 are used as backup transmission paths.
[0016]
Next, the configuration of the in-station subscriber accommodation apparatus LT1 described above will be described with reference to FIG. FIG. 2 is a block diagram showing functional blocks of the in-station subscriber accommodation apparatus of the first embodiment. In the first embodiment, only functional blocks related to the present invention in the configuration of each device LT1 will be described, and description of other functions will be omitted.
[0017]
In FIG. 2, the in-station subscriber accommodation apparatus LT <b> 1 has a link disconnection detection unit 21 and a signal output stop unit 22. The link disconnection detection means 21 has a function of monitoring the link state with the cable 3 and outputting a link disconnection detection signal when the link state is disconnected. The signal output stop unit 22 has a function of monitoring the link disconnection detection signal and stopping the signal output to the optical fiber 4 when the link disconnection detection signal is input. The link disconnection detection means 21 monitors a specific control signal transmitted from the spanning tree bridge device 2 and outputs a link disconnection detection signal when the control signal is not confirmed for a predetermined period shorter than the BPDU transmission interval. To do. For example, when the cable 3 is a twisted pair cable conforming to the 10BASE-T standard, the link break detection means 21 monitors NLPs (Normal Link Pulse) from the spanning tree bridge device 2 for a predetermined period (1 second). When there is no link break detection signal is output. Further, when the in-station subscriber accommodation device LT1 conforms to the standards of 100BASE-FX, 1000BASE-T, 1000BASE-SX, or 1000BASE-LX, the Scrambled Idle transmitted from the spanning tree bridge device 2 periodically. Link disconnection is detected by monitoring the signal.
[0018]
The in-home subscriber terminating device NT11 has link disconnection detecting means and signal output stopping means (not shown) as in the in-house subscriber accommodation device LT1. The link disconnection detecting means of the home subscriber terminating device NT11 monitors a specific control signal transmitted from the in-house subscriber accommodating device LT1, and if the control signal is not confirmed for a predetermined period shorter than the transmission interval of the BPDU, Outputs a link disconnection detection signal. For example, the link disconnection detection means monitors an idle pattern existing between valid packet signals transmitted from the in-station subscriber accommodation apparatus LT1 via the star coupler SC1, and the idle pattern corresponds to three times the maximum packet length. If it is not detected during this period, it is determined as LOF (Loss Of Frame), and it is recognized that the link state with the in-station subscriber accommodation apparatus LT1 is disconnected.
[0019]
Further, the link disconnection detecting means of the in-home subscriber terminating device NT11 has a function of detecting that the in-station subscriber accommodating device LT1 has stopped signal output. With regard to this function, for example, when the signal output from the in-house subscriber accommodation device LT1 is not detected for a predetermined time shorter than the BPDU transmission interval in the in-station subscriber accommodation device 2, it is recognized that the link state is disconnected. In the first embodiment, since the in-house subscriber accommodation device LT1 and the in-home subscriber terminator NT11 are connected by an optical fiber, the optical signal input to the in-home subscriber terminator NT11 is the transmission interval of the BPDU. When it is not detected for a shorter predetermined time (for example, 1 second), it is determined as LOS (Loss of signal), and it is recognized that the link state with the in-station subscriber accommodation apparatus LT1 is disconnected. The home subscriber terminal device NT11 has a function of stopping signal output to the spanning tree bridge device 11 when recognizing that the link state is disconnected.
[0020]
Next, the configuration of the above-described spanning tree bridge device 11 will be described with reference to FIG. FIG. 3 is a configuration diagram showing the spanning tree bridge device 11 according to the first embodiment in functional blocks. In the first embodiment, only functional blocks related to the present invention in the configuration of the spanning tree bridge device 11 will be described, and description of other functions will be omitted.
[0021]
In FIG. 3, the spanning tree bridge device 11 includes a timeout detection unit 31, a link disconnection detection unit 32, and a port setting change unit 33. The timeout detection unit 31 monitors the BPDU received by the port 11a, and outputs a timeout detection signal when the BPDU is not detected for a predetermined timeout setting time (20 seconds in this embodiment). The link disconnection detection unit 32 has a function of monitoring a signal received by the port 11a and monitoring a signal transmitted at an interval shorter than the BPDU transmission interval in the spanning tree bridge device 2. Further, the link disconnection detection means 32 has a function of detecting that the subscriber subscriber terminal device NT11 stops outputting the signal, that is, a signal output from the subscriber subscriber accommodation device LT1 is shorter than a BPDU transmission interval (for example, It has a function of recognizing that the link state is broken when it is not detected for 1 second. The link break detection means 32 is in a link state.CuttingWhen it is recognized that the link has been detected, a link disconnection detection signal is output.
[0022]
The port setting changing unit 33 has a function of changing the state of the ports 11a and 11b when a timeout detection signal or a link disconnection detection signal is output from either the timeout detection unit 31 or the link disconnection detection unit 32. Yes. That is, when receiving the timeout detection signal or the link disconnection detection signal, the port setting changing unit 33 changes the state of the port 11a from the root port to the closed port and changes the state of the port 11b from the closed port to the root port. With this change, in the spanning tree bridge device 11, the port 11 b becomes ready for signal transmission / reception with the transmission path 10.
[0023]
In the first embodiment, the sum of each of the predetermined periods for monitoring in the link disconnection detecting means of the in-house subscriber accommodation device LT1, the in-home subscriber termination device NT11, and the spanning tree bridge device 11 is the spanning tree. The time is set to be shorter than the time-out setting time of the time-out detecting means of the bridge device 11, and can be arbitrarily changed within a range satisfying this condition.
[0024]
In the EPON system 1 configured as described above, a case where a failure occurs in the working transmission path between the spanning tree bridge device 2 and the spanning tree bridge device 11 will be described.
[0025]
In FIG. 2, when a failure occurs in the cable 3, the control signal to be transmitted from the spanning tree bridge device 2 by the link break detection means 21 of the intra-station subscriber accommodation device LT 1 is transmitted by the BPDU in the spanning tree bridge device 2. When it is not detected for a period shorter than the interval, it recognizes that the link state with the cable 3 has been disconnected, and outputs a link disconnection detection signal. The signal output stop means 22 receives this link disconnection detection signal and stops signal output to the optical fiber 4. The intra-station subscriber accommodation apparatus LT1 can detect the disconnection of the link state in a time shorter than the BPDU transmission interval in the spanning tree bridge apparatus 2.
[0026]
Since the signal output from the in-station subscriber accommodation device LT1 is stopped, the in-home subscriber terminating device NT11 stops the signal output to the cable 9. In the subscriber subscriber unit NT11, the disconnection of the link state can be detected in a time shorter than the BPDU transmission interval in the spanning tree bridge device 2.
[0027]
The link disconnection detection means 32 of the spanning tree bridge device 11 outputs a link disconnection detection signal because the subscriber subscriber terminal device NT11 stops outputting the signal. Also in this spanning tree bridge device 11, the disconnection of the link state can be detected in a time shorter than the BPDU transmission interval in the spanning tree bridge device 2. Therefore, the link disconnection detection unit 32 of the spanning tree bridge device 11 performs the processing from when a failure occurs in the cable 3 until the link disconnection detection signal is output in a time shorter than the timeout setting time in the timeout detection unit 31. It becomes possible to execute.
[0028]
The port setting changing unit 33 changes the state of the port 11a to a closed port and changes the state of the port 11b to a root port. The port 11b changed to the root port outputs a TCN-BPDU (Topology Change Notification BPDU) in order to notify the spanning tree bridge device 2 that reconfiguration has occurred in the spanning tree according to the spanning tree protocol. The TCN-BPDU is transmitted to the spanning tree bridge device 2 via the subscriber termination device NT21, the star coupler SC2, and the in-house subscriber accommodation device LT2. The spanning tree bridge device 2 uses the received TCN-BPDU to perform spanning tree reconfiguration processing according to the spanning tree protocol, thereby transmitting a transmission path between the spanning tree bridge device 2 and the spanning tree bridge device 11. Can be changed from the active system to the standby system.
[0029]
In FIG. 1, when a failure occurs in any one of the optical fiber 4, the star coupler SC1, and the optical fiber 51, it is detected that the link state is disconnected in the home subscriber terminal device NT11 and the transmission path 9 is entered. Signal output is stopped, and subsequent processing is performed in the same manner as described above.
[0030]
In the first embodiment, by shortening the failure detection time in the spanning tree bridge device 11, it is possible to execute the change from the active transmission path to the standby transmission path in a short time. .
[0031]
(Embodiment 2)
Next, a second embodiment of the present invention will be described with reference to FIG. FIG. 4 is a block diagram showing functional blocks of the intra-station subscriber accommodation apparatus according to the second embodiment, and corresponds to FIG. 2 in the first embodiment. In the description of the second embodiment, components corresponding to those of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0032]
In FIG. 4, the in-station subscriber accommodation apparatus LT1 includes link disconnection detection means 41 and 42 and a signal output stop means 43. The link disconnection detection unit 41 has the same function as the link disconnection detection unit 21 and has a function of monitoring the link state with the cable 3 and outputting a link disconnection detection signal when the link state is disconnected. Have. The link disconnection detection means 42 has a function of monitoring the link state with the optical fiber 4 and outputting a link disconnection detection signal when the link state is disconnected. The signal output stop unit 43 monitors each link disconnection detection signal input from the link disconnection detection unit 41, 42. When the link disconnection detection signal is input from either one of the link disconnection detection units 41, 42, the signal output stop unit 43 It has a function of stopping signal output to the fiber 4.
[0033]
In the second embodiment, in the signal transmission from each home subscriber terminal device NT11,..., NT1n to the in-house subscriber accommodation device LT1, the bandwidth used by each home subscriber terminal device NT11,. Each is performed by a time division multiplex transmission system in which a signal is transmitted in a predetermined time slot. In the in-house subscriber accommodation device LT1, the link disconnection detecting means 42 monitors the timing of each signal transmitted from each in-home subscriber terminator NT11,..., NT1n, and each in-home subscriber terminator NT11,. A link disconnection detection signal is output when the transmission signal from the terminal does not follow a predetermined time slot.
[0034]
According to the second embodiment, in the EPON system 1 shown in FIG. 1, if a failure occurs in any of the optical fiber 4, the star coupler SC1, or the optical fibers 51,. In LT1, the link disconnection detecting means 42 detects that the link state with the optical fiber 4 is disconnected, and the signal output stop means 43 stops signal output to the optical fiber 4. In the same way as in the first embodiment, the home subscriber terminating device NT11 detects that the signal output stopping means 43 has stopped outputting the signal to the optical fiber 4, and stops the signal output to the spanning tree bridge device 11. . Thereafter, the spanning tree bridge device 11 performs the same processing as in the first embodiment, and can detect the occurrence of a failure in a time shorter than the time-out setting time in the time-out detection means 31.
[0035]
In the second embodiment, in addition to the first embodiment described above, a spanning tree bridge device is also provided for a failure in signal transmission from each of the in-home subscriber terminal devices NT11,..., NT1n to the in-house subscriber accommodation device LT1. 11 can be detected in a short time.
[0036]
【The invention's effect】
As described above, according to the communication system of the present invention, the first port which has the first port and the second port, changes the state of each port according to the spanning tree protocol, and outputs the BPDU from the first port. A spanning tree bridge device, a first transmission path connected to the first port,A transmission device provided in the first transmission path;A second transmission path connected to the second port, a third port connected to the other end of the first transmission path, and a fourth port connected to the other end of the second transmission path; A communication system comprising a second spanning tree bridge device for changing the states of the third and fourth ports according to a spanning tree protocol,The transmission apparatus monitors a control signal transmitted from the first spanning tree bridge apparatus, and detects a link break when the control signal is not detected for a predetermined period shorter than the BPDU transmission interval. Means for stopping signal output to the second spanning tree bridge device when detectingThe second spanning tree bridge device is:From transmission equipmentMonitor the received signal to the third portFaithIssuePredetermined shorter than BPDU transmission intervalA link break detection means for outputting a link break detection signal when no period is detected;,NCut offDetection signalIssuePort setting changing means for changing the third port to a closed port and changing the fourth port to a root port when input is provided. For this reason, when a failure occurs in the first transmission path, it is possible to shorten the time until the transmission path to be used is changed to the second transmission path.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of an EPON system in a first embodiment.
FIG. 2 is a block diagram showing functional blocks of the in-station subscriber accommodation apparatus of the first embodiment.
FIG. 3 is a block diagram showing functional blocks of the spanning tree bridge device 11 according to the first embodiment.
FIG. 4 is a block diagram showing functional blocks of the intra-station subscriber accommodation apparatus of the second embodiment, corresponding to FIG. 2 in the first embodiment.
[Explanation of symbols]
LT1, LT2 ... Intra-station subscriber accommodation device, NT11-NT1n, NT21-NT2n ... In-home subscriber termination device, SC1, SC2 ... Star coupler.
DESCRIPTION OF SYMBOLS 1 ... EPON system, 2,11 ... Spanning tree bridge device, 2a, 2b, 11a, 11b ... Port, 3, 6, 9, 10 ... Cable, 4, 51-5n, 7, 81-8n ... Optical fiber 21, 41, 42, link disconnection detection means, 22, 43, signal output stop means, 31, timeout detection means, 32, link disconnection detection means, 33 ... port setting change means

Claims (4)

A first spanning tree bridge device that has a first port and a second port, changes a state of each port according to a spanning tree protocol, and outputs a BPDU from the first port; and is connected to the first port A first transmission path; a transmission device included in the first transmission path; a second transmission path connected to the second port; a third port connected to the other end of the first transmission path; A communication system comprising a second spanning tree bridge device having a fourth port connected to the other end of the transmission path and changing the states of the third and fourth ports according to the spanning tree protocol. ,
The transmission device monitors a control signal transmitted from the first spanning tree bridge device, and detects a link break when the control signal is not detected for a predetermined period shorter than the transmission interval of the BPDU, Means for stopping signal output to the second spanning tree bridge device when the link break is detected;
The second spanning tree bridge apparatus, when monitoring the received signals those receiving Sing Sing No. not detected short predetermined period of time than the transmission interval of the BPDU to the link disconnection detection from the transmission device to the third port a link disconnection detecting means for outputting a signal, that a port setting changing means for changing the third port and a closed port and the fourth port if you enter a re down click-off detection signal as a root port A communication system characterized by the above. A first spanning tree bridge device that has a first port and a second port, changes a state of each port according to a spanning tree protocol, and outputs a BPDU from the first port; and is connected to the first port Connected to the first transmission path, the first transmission apparatus and the second transmission apparatus included in the first transmission path, the second transmission path connected to the second port, and the other end of the first transmission path A second spanning tree bridge device having a third port and a fourth port connected to the other end of the second transmission path and changing the state of the third and fourth ports according to the spanning tree protocol; A communication system comprising:
The first transmission device monitors a control signal transmitted from the first spanning tree bridge device, and if the control signal is not detected for a predetermined period shorter than the transmission interval of the BPDU, the link is disconnected. Means for detecting and stopping signal output to the second transmission device when the link break is detected;
The second transmission device monitors a control signal transmitted from the first transmission device, and detects a link break when the control signal is not detected for a predetermined period shorter than the transmission interval of the BPDU, The means for stopping signal output to the second spanning tree bridge device when the link break is detected, and the received signal from the first transmission device are monitored, and the received signal is detected from the transmission interval of the BPDU. A means for detecting a link break when the short predetermined period is not detected, and stopping signal output to the second spanning tree bridge device when the link break is detected;
The second spanning tree bridge device monitors a received signal from the second transmission device to the third port, and when the received signal is not detected for a predetermined period shorter than the transmission interval of the BPDU, the link is disconnected. Link break detection means for outputting a detection signal, and port setting change means for changing the third port to a closed port and changing the fourth port to a root port when a link break detection signal is input. A communication system. A third port connected to a first spanning tree bridge device that outputs a BPDU via a first transmission path that is set as a root port and includes a transmission device; In the method for changing the port state of the second spanning tree bridge device having a fourth port connected to the first spanning tree bridge device,
A step of monitoring the control signal transmitted from the first spanning tree bridge device by the transmission device, and a step of detecting a link break if the control signal is not detected for a predetermined period shorter than the transmission interval of the BPDU. When the link break is detected, the second Stopping signal output to the spanning tree bridge device;
The second spanning tree device monitors a received signal from the transmission device to the third port, and detects a link break if the received signal is not detected for a predetermined period shorter than the transmission interval of the BPDU. And a step of changing the third port as a closed port and changing the fourth port as a root port when the link break is detected. A third port connected to a first spanning tree bridge device that outputs a BPDU via a first transmission path that is set as a root port and includes a first transmission device and a second transmission device, and a closed port And a port state changing method for a second spanning tree bridge device having a fourth port connected to the first spanning tree bridge device via a second transmission path,
A step of monitoring a control signal transmitted from the first spanning tree bridge device by the first transmission device; and a link disconnection when the control signal is not detected for a predetermined period shorter than the transmission interval of the BPDU. Detecting, and stopping signal output to the second transmission device when the link break is detected;
The second transmission device monitoring a received signal from the first transmission device; detecting a link break if the received signal is not detected for a predetermined period shorter than the transmission interval of the BPDU; Stopping signal output to the second spanning tree bridge device when the link break is detected;
The second spanning tree device monitors the received signal from the second transmission device to the third port, and when the received signal is not detected for a predetermined period shorter than the transmission interval of the BPDU, the link is broken. And a step of changing the third port as a closed port and changing the fourth port as a root port when the link break is detected.

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