JPH08181773A - Signal fault processing system - Google Patents

Abstract

PURPOSE: To surely detect a fault and to restore the fault properly. CONSTITUTION: When a data link setting request comes from a setting request section 1b of an opposite station, its own station makes a reply with the request and a setting request section 1a sends a data link setting request to the opposite station. Then after a reply from the opposite station, a data link of its own station is set. Furthermore, on the occurrence of a fault in a communication path from its own station to the opposite station, a response from its own station to the opposite station is not reached with respect to a command from the opposite station to its own station and the opposite station detects a link fault after the elapse of a prescribed time. On the other hand, since a command from its own station to the opposite station is not reached, no response comes from the opposite station. In this case, the link setting section 2b of the opposite station sends again a data link setting request in a timing after the elapse of a prescribed time after the occurrence of the link fault. The timing is set after retransmission of the command from its own station to the opposite station is repeated and the time expires.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a signal fault handling system for a switching system having an ISDN interface.

[0002]

2. Description of the Related Art Conventionally, in constructing a communication network using a leased line network, there is a common line signaling system using an ISDN protocol as a method of communicating an inter-station signal between exchanges. In this method, the occurrence of a communication path failure is detected as follows. That is, the RR for the RR (Receive Ready) command that inquires whether the frame can be received.
If there is a response, it will be normal. On the other hand, if there is no RR response after the response waiting time T200 has elapsed after transmitting the RR command, the RR command is retransmitted. And
If there is no RR response even if the retransmission is repeated a predetermined number of times, for example, three times, it is a link setting request, and SABME (S
et Asynchronous Balanced Mode Extended) command is sent. Furthermore, the UA for this SABME command
(Unnumbered Acknowledge) Response is response waiting time T
If it is not after 200 seconds, the SABME command is retransmitted. If no UA response is received, it is considered as a link failure. At this point a link failure is detected.

[0003]

However, the above-mentioned conventional techniques have the following problems. That is, S
In the exchange that transmits the ABME command, the S switch is restarted at a timing after a predetermined time has elapsed from the detection of the link failure.
Send ABME command multiple times, but SAB
The exchange that receives the ME command cannot detect the failure if this timing is early. Also, if this timing is late, the failure can be detected even by the exchange that receives the SABME command.
When the E command was received, the failure was recovered even though this response did not reach the exchange that sent the SABME command when the UA response was sent.

[0004]

In order to solve the above-mentioned problems, the signal failure processing system of the present invention is characterized by the following points in a system for setting mutual data links between exchanges. . (1) After detecting the data link failure of one of the exchanges, the timing of outputting the link setting request is set later than the predetermined timing corresponding to the timer value for monitoring the time during which the communication is interrupted during the setting of the data link. And a setting request unit for performing the setting. After receiving the link setting request output from the setting request unit of the one exchange, output the link setting request from the other exchange, and after confirming the setting state of the data link in the one exchange, the data of the other exchange. A link setting unit that sets a link is provided.

(2) In (1), the ISDN standard protocol (JT-Q92) is used for the setting request section and the link setting section.
1, Q931).

[0006]

[Action]

(1) When there is a data link setting request from the opposite station, the own station also responds to it, and then the setting request unit transmits a data link setting request to the opposite station. Then, after receiving a response from the opposite station, the data link is set in the own station. Also, when a failure occurs in the communication path from the own station to the opposite station, the response from the own station to the opposite station does not reach the command from the opposite station to the own station,
A link failure is detected in the opposite station after a lapse of a predetermined time. On the other hand, there is no response from the opposite station because the command from the own station does not reach the opposite station. At this time, the link setting unit of the opposite station retransmits the data link setting request at a timing after a lapse of a predetermined time after the occurrence of the link failure. This timing is set after the command is repeatedly retransmitted from the own station to the opposite station and a timeout occurs. Therefore, the own station surely times out the response to the command transmission, and as a result, the own station can surely detect the occurrence of the failure. Also, in response to a data link setting request from the opposite station, the local station also sends a data link setting request to the opposite station, waits for a response from the opposite station and sets the data link, and as a result, the failure of the communication path is repaired. It prevents the local station from entering the failure recovery state when it is not.

(2) In (1), the ISDN standard protocol (JT-Q92) is used for the setting request section and the link setting section.
1, Q931), the exchange according to the present invention can be interconnected with the exchange according to the ISDN standard protocol and to which the present invention is not applied.

[0008]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 1 is a block diagram of an embodiment of the signal fault processing system of the present invention. The illustrated apparatus includes setting requesting units 1a, 1b, 1c and link setting units 2a, 2b, 2c.

After detecting the data link failure of the exchange, each setting requesting unit 1a, 1b, 1c transmits the data link setting request again in order to recover from the failure. This transmission timing is set to be later than a predetermined timing corresponding to a timer value that monitors the time during which communication is interrupted during the setting of the data link. Specifically, ISDN layer 2
With the parameters used in (L2), (T203 + T200 ×
4) Make it more than a second. That is, the timing X from the release display detection to the release request issuance is set to (T203 + T200 × 4) seconds or more. Thus, in FIG. 1, the PBX (A) of the own station can surely detect the data link release.

Each link setting unit 2a, 2b, 2c receives a data link setting request from the exchange of its own station after receiving the data link setting request output from the setting request unit 1a, 1b, 1c of the exchange of the opposite station. Output a certain SABME command. Then, the UA that is the response from the exchange of the opposite station
After confirming the response, set up the data link of the local exchange. That is, the layer 3 (L3) detects once the data link failure and then detects the link failure recovery by the U from the opposite station in response to the data link setting request from the own station.
Assume that the A response is received. As a result, the local station can surely detect the data link failure. The electrical interface between the PRI and the MUX in FIG. 1 is a so-called TTC2M interface (TTC standard JJ-20.X) as shown in FIG. 2 or a primary group velocity interface (TTC standard JT as shown in FIG. 3).
I431). The TTC2M interface will be described below.

As shown in FIG. 2, PBX (A) -MUX
In between, there are 30 traffic channels.
The 30 traffic channels are divided into a plurality of routes, and the routes are divided. In this case, a signal channel for inter-station signal communication is assigned to each route division group. For example,
In the case of the network configuration of FIG. 1, PBX (A)
From the viewpoint of the above, channels # 1 to # 5 are allocated to the route to PBX (B), and among them, # 1 is allocated.
Are assigned to the control channel for inter-station signal communication (hereinafter referred to as D channel), and the remaining # 2 to # 5 are assigned to traffic channels controlled by the channel. And
Channels # 6 to # 11 are assigned to the route to the PBX (C), # 6 is assigned to the D channel, and # 7 to # 11 are assigned.
It is possible to consider a configuration in which is assigned to the traffic channel.

On the other hand, in the network having such a configuration, the direct route of PBX (A) -PBX (B) is M
If communication failure occurs due to a failure between UXes,
The PBX (A) closes the route to the route to the PBX (B) and connects to the PBX (B) via the PBX (C) route, so-called “detour” is performed. Here, failure detection and recovery processing when a one-line disconnection failure as shown in FIG. 1 occurs becomes a problem.

In the common channel signaling system using the D channel as described above, if the communication failure due to the transmission path failure between the MUXs is made, the failure recovery detection is judged from the D channel data link state, and the D channel data link is detected. When the disconnection occurs, the status becomes "failure", and the blocking process is performed. On the other hand, when the data link is established, "failure recovery" is set, and the block is released. Here, as the D channel data link protocol, a so-called ISDN standard LAPD protocol (TTC standard JT-Q921) is used. This is to ensure mutual connectivity.

Next, the operation of the above-mentioned device when a failure is detected will be described. First, the occurrence status of a failure will be described. As shown in FIG. 4, when the communication system is started up, the SABME command is transmitted from the opposite station to its own station. As a result, in the own station, the data link (DL) setting display goes up from L2. In response to this, the UA response is transmitted from the own station to the opposite station. As a result, the opposite station confirms the DL setting and sets the link.

On the other hand, the own station does not immediately perform the link setting by the DL setting display, but first transmits the SABME command to the opposite station. Then, a UA response is returned from the opposite station to the own station, the DL setting is confirmed in the own station, and then the link setting is performed. After that, in the case of information transfer, an I (Information) frame not shown is transmitted. On the other hand, I
If the frame is not transmitted, it indicates that the frame can be received.
The R response is transmitted and received.

As shown by the "X" mark in FIG.
When the transmission side transmission line FC1 from the PBX (A) is disconnected, the electrical interfaces FC2 and FC4 of the PBX (A) and the MUX (A) do not become a failure. Therefore, PBX
From the perspective of (A), L between PBX (A) and MUX (A)
1 is normal. Transmission side FC from PBX (A)
When only 1 is disconnected, as shown in FIG. 4, the RR command from the opposite station to its own station arrives via FC3,
The RR response from the own station to the opposite station will not arrive.
Therefore, as shown in the figure, the RR command is retransmitted from the opposite station after T200 (default value, 1 second), which is N20.
Repeated 0 (default value, 3 times).

After that, as shown in FIG. 5, after the timeout, the SABME command is transmitted from the opposite station to the own station. On the other hand, although the UA response is returned from the own station to the opposite station, it does not reach the opposite station due to a line failure. For this reason, as shown in the figure, the SABM is set 200 seconds after the opposite station.
The E command is retransmitted and this is repeated N200 times.
Then, the link failure is detected by the time out (TO) in the opposite station. When the link failure due to the one-way failure is detected, the L2 of the PBX (B) notifies the data link failure to the L3, so that the PBX (B) side performs the blocking processing of the line.

On the other hand, in its own station, T203 (default value,
After 10 seconds, the RR command is transmitted to the opposite station. However, due to the line failure, this does not reach the opposite station, and therefore the RR response is not returned from the opposite station. In this case, the own station retransmits the RR command at intervals of
Repeat times. Then, after T200 seconds, S from the own station to the opposite station
The ABME command is sent. The transmission timing of this SABME command is (T203 + T
200 x 4) (default value, 14 seconds).

On the other hand, in the opposite station, after detecting the link failure,
A data link setting request is issued at a predetermined timing X, and S
Send the ABME command. The timing X of the data link setting request from the opposite station PBX (B) side to the own station PBX (A) is not specified in the ISDN standard, but in the present invention, (T203 + T20).
0 x 4) (default value, 14 seconds) or more. This is for the following reason. As shown in FIGS. 7 and 8, if the timing X is before (T203 + T200 × 4) seconds, the data link release indication is L on the PBX (A) side.
Before being notified to 3, T203 is returned by the return of the UA response due to the reception of the data link setting request from the PBX (B) side.
The timer is restarted. As a result, the data link failure cannot be detected in the own station even though the one line is completely disconnected.

As a result, the line on the side of the own station PBX (A) is not closed and communication is impossible, but no fault condition is detected, and L3 (the call processing program of the exchange) is I try to hunt the line. To prevent this, set the timing X to (T203 + T
After 200 × 4) seconds have passed. As a result, as shown in FIG. 6, the link failure is surely detected at the own station. And
The L2 of the PBX (A) notifies the data link failure to the L3, and the blocking process of the line is also performed on the PBX (A) side.

In FIG. 6, when the SABME command from the opposite station is received during the link failure at the own station, L2 becomes L
Increase the data link (DL) setting display for 3. In this case, the L3 side does not restore the data link and discards this display. After that, also in PBX (A),
Similar to PBX (B), L3 is reached after (T203 + T200 × 4) seconds have passed since the detection of the link failure by the DL release indication.
Issues a DL setting request from L2, and L2 sends a SABME command to PBX (B).

The reason for this is as follows. If the timing X is set to (T203 + T200 × 4) seconds as described above, the L2 of the PBX (A) sends a data link release indication to the L3, and the line is temporarily linked. Become a fault condition. However, after that, when the PBX (A) side receives a data link setting request from the PBX (B) side, the data link is restored when the UA response is returned to the PBX (B) side. As a result, in such a case, failure recovery of the line is repeated on the PBX (A) side even though one line is completely disconnected. In order to prevent this, the data link setting request is also transmitted from the local station side.

Accordingly, even when the communication system is started up, as described above, the DL setting display and SA shown in FIG. 4 are displayed.
The BME command is transmitted. When the SABME command is transmitted after the DL setting shown in FIG. 6 and the one-line fault of the MUX transmission path is not recovered, the SABME command does not reach the opposite station, unlike the case shown in the figure. Therefore, the UA response is not returned to the own station. Also,
No UA response is sent from the own station to the opposite station. Therefore, the fault condition continues in both the own station and the opposite station. During the failure state, the local station side closes the line and performs a bypass process if there is a bypass route. That is, in FIG. 1, communication with the opposite station is performed via the PBX (C).

On the other hand, when the transmission line fault between the MUXs is restored, as shown in FIG. 6, the SABME command from the own station reaches the opposite station, and the L2 of the own station receives the UA response from the opposite station. To do. The L2 of its own station notifies the L3 of the DL release confirmation, and at this point, it shifts to the data link setting state for the first time, and the own station releases the blockage of the line and performs the detour release process.

In this way, it is possible to eliminate a failure such as a failure that cannot be detected at the time of a one-way failure in the transmission line between MUXs, or to repeat failure recovery and detection. It is possible to execute the blockage process and the bypass process. Further, the exchange according to the present invention is an ISDN standard protocol (JT-Q921, Q93).
Since it is not contrary to 1), it is also possible to perform interconnection with an exchange to which the present invention is not applied in accordance with the ISDN standard protocol.

The present invention is not limited to the above-mentioned embodiments, and it goes without saying that various modifications can be made. For example, the so-called TTC2 is between the PBX and MUX.
M (PBX-MUX 2M interface TTC JJ
It is not limited to the (-20 series) interface and can be applied to the primary group speed interface (JT-I431). In addition, the present invention is a PBX-
In a network configuration in which MUXes are connected by multiplex transmission lines and routes are divided from the MUXes ahead, PB
The communication of the control information between the Xs uses the D channel common line, and it can be applied to all cases in which the failure detection and restoration on the transmission path of the route are performed using the signal on the D channel.

[0027]

As described above, according to the signal failure processing system of the present invention, the transmission timing of the data link setting request for recovering the failure is optimized so that not only the opposite station but also the own station can request the data link setting request. Since it is set to send, there is the following effect. In other words, the data link setting request sent from the exchange of the opposite station for recovery from the failure does not prevent the operation of detecting the link failure in the own station, and the switch of the own station can reliably detect the failure. it can. Also, in response to a data link setting request from the opposite station, a data link setting request from the own station to the opposite station
It is possible to confirm the repaired state of the line, and it is possible to prevent the own station from performing the failure recovery operation while the line is not repaired.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of a signal fault processing system of the present invention.

FIG. 2 is an explanatory diagram of an example of a frame configuration.

FIG. 3 is an explanatory diagram of another example of a frame configuration.

FIG. 4 is an explanatory diagram of a signal failure processing procedure (No. 1) according to the present invention.

FIG. 5 is an explanatory diagram of a signal failure processing procedure (No. 2) according to the present invention.

FIG. 6 is an explanatory diagram of a signal failure processing procedure (No. 3) according to the present invention.

FIG. 7 is an explanatory diagram of a conventional signal failure processing procedure (No. 1).

FIG. 8 is an explanatory diagram of a conventional signal failure processing procedure (No. 2).

[Explanation of symbols]

 1a, 1b, 1c setting requesting section 2a, 2b, 2c link setting section

Claims (2)

[Claims] 1. In a system in which mutual data links are set up between exchanges, after detecting a data link failure of one of the exchanges, the timing for outputting a link setup request is set such that communication is interrupted during data link setup. After receiving the link setting request output from the setting requesting unit of one of the exchanges and the setting requesting unit that sets the timing later than the predetermined timing corresponding to the timer value that monitors the remaining time, the link setting request from the other switching A signal failure processing system, comprising: a link setting unit that outputs and confirms a data link setting state in the one exchange, and then sets a data link in the other exchange. 2. The signal failure processing system according to claim 1, wherein the setting requesting unit and the link setting unit comply with an ISDN standard protocol.