JPH09321773A - Active and reserve switching method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform current/stand-by switching without generating the lost transfer data in an active/reserve switching method for a frame relay protocol processing part. SOLUTION: By a switch instruction from a control part 7, the content of a logic-physial transformation table 10 showing the logical number and the physical number of frame relay protocol processing parts 2-1 to 2-n is rewritten to multi-separate cell data through a relay line part 5 and a cell switch part 4 to transfer the same cell data added with copy display to the relay protocol processing parts 2-1 to 2-n of an active system and a reserved system. Next, the copy display identification parts 12 of the relay protocol processing parts 2-1 to 2-n identifies copy display, a cell-frame transformation part 9 composes cell data to be a frame, the stand-by system sends frames after the completing the composition of the frame to a subscriber's terminal equipment 8 through a time division switch part 1 and the current system stops cell-frame transforming processing after the completing the composition of the frame of the reserved system.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a frame relay / protocol processing unit of an active system (active system) and a standby system (standby system) for framing cell data in an exchange and cellizing frame data. The present invention relates to a standby switching method.
A system is known in which frame data is transmitted / received to / from a subscriber terminal device, and high-speed transfer is performed as cell data between exchanges via a network. The frame relay exchange in such a system is provided with a frame relay protocol processing unit that divides frame data into cells and assembles the cell data into a frame. For example, N (N = any integer). ) M (M = arbitrary integer) spare frame relay protocol processing units are provided for each active frame relay protocol processing unit, and the active system is used when a failure occurs in the active system or during maintenance. The frame relay / protocol processing unit is switched to the standby frame relay / protocol processing unit. In this case, it is desired to prevent loss of transfer data when switching the active spare.

[0002]

2. Description of the Related Art FIG. 4 is an explanatory diagram of a system configuration.
0 and 30 are frame relay exchanges, 40 is ATM network, 2
Reference numerals 1 and 31 are time division switch units, 22 and 32 are frame relay protocol processing units having an N-to-M active redundant structure, 23 and 33 are multiplexing units, 24 and 34 are cell switch units, and 25 and 35 are relays. Lines 26, 36 denote subscriber terminal devices.

ATM (Asynchronous Transfer Mode)
(Asynchronous transfer mode) shows a case where the frame relay exchanges 20 and 30 are connected via the network 40, and the frame relay exchanges 20 and 30 perform exchange connection of frame data with the subscriber terminal devices 26 and 36. Time division switch units 21 and 31, and frame relay protocol processing units 22 and 3 for converting between frame data and cell data.
2 and a multiplexing unit 2 for multiplexing and demultiplexing cell data
3, 33, cell switch units 24, 34 for exchanging cell data, and relay line units 25, 35. The frame relay protocol processing units 22 and 32 are
An N-to-M active spare configuration having N active systems and M standby systems is used, and N and M are selected as arbitrary integers corresponding to the system scale.

The frame-relay protocol processing units 22 and 32 of the N-to-M active spare configuration perform conversion processing between cell data such as ATM cells and frame data such as variable-length frames. The switching is performed by controlling the time division switch units 21 and 31 and the multiplexing units 23 and 33, and conventionally, the following switching method has been adopted. That is, the first method switches the active system in which a failure has occurred to the standby system only when a failure has occurred. In this case, loss of transfer data is not guaranteed. In the second method, the frame relay protocol processing section of the opposite frame relay exchange is subjected to transmission restriction, and the active system is switched to the standby system when the reception is stopped. The third method is the subscriber terminal device 2
After congestion control is applied to 6 and 36 to stop the transmission and the data accumulated in the frame relay exchange is transmitted, the active system is switched to the standby system.

[0005]

The first method of the above-mentioned conventional example is premised on that the active spare is not switched except for the occurrence of a failure. When the failure occurs, the transfer data is not lost. It is unavoidable that the active spare will be forcibly switched. Therefore, it has been impossible to switch the active spare during maintenance of the active system or when confirming the normality of the standby system.

In the second method, it is necessary to restrict transmission to the opposite frame relay exchange even in the active standby switching in the own frame relay exchange. There was a problem that the active spare could not be switched until the switching preparation process was completed.

The third method is the subscriber terminal device 26, 3
6 may not have a congestion control function. In this case, the congestion control at the time of the active protection switching cannot be applied. Even if the congestion control function is provided, the opposite frame relay switch is provided. Since the data from the side is not stopped, there is a problem that the loss probability of the transfer data may be reduced and the transfer data may be lost. SUMMARY OF THE INVENTION It is an object of the present invention to eliminate loss of transfer data when switching a working spare of a frame relay protocol processing unit.

[0008]

According to the present invention, there is provided an active backup switching method comprising: (1) an active backup switching method of a frame relay protocol processing unit for converting cell data into frames and converting the frame data into cells; In response to the spare switching instruction, the cell data with the copy display is transferred to both the active frame relay / protocol processing unit and the standby system frame relay / protocol processing unit, and the frame with the cell data with the copy display is transferred. This includes a process of switching the processing operation between the active frame relay protocol processing unit and the standby frame relay protocol processing unit when the assembly is completed. Therefore, since the active spare is switched at the time of completion of assembling one frame data by the cell data to which the copy display is added, the transfer data will not be lost.

(2) A plurality of frame relay / protocol processing units, each of which is composed of a plurality of active systems and an arbitrary number of spare systems, forms cell data into frames and converts the frame data into cells, and exchange connection of the frame data. The frame relay of the frame relay switch having a time division switch unit for performing the above, a multiplexing unit for multiplexing and demultiplexing cell data, a cell switch unit for switching and connecting cell data, and a control unit for controlling each unit. In the active standby switching method of the protocol processing unit, the multiplexing unit adds a copy display to the cell data in response to the active standby switching instruction from the control unit, and the active frame relay protocol processing unit and the standby system frame are added. Transfer to both the relay protocol processing unit,
The active frame relay / protocol processing unit sends a frame of completion of assembly of cell data to which a copy display is added to the subscriber terminal device via the time division switch unit,
The processing is stopped, and the frame relay protocol processing unit of the standby system discards the assembly completion frame of the cell data to which the copy display is added, and the frames assembled after this frame are passed through the time division switch unit to the subscriber terminal. It includes the process of sending to the device.

(3) The multiplexer includes a logical-physical conversion table that associates the logical number of the demultiplexed cell data with the physical number of the frame relay protocol processing unit that transfers the cell data, and controls In response to an instruction to switch between the active and standby units, the logical number corresponding to the physical number of the active system frame relay / protocol processing unit and the physical number of the standby system frame relay / protocol processing unit in the logical-physical conversion table. And a copy display is added to the cell data according to this logical number, and the cell data is transferred to both the active frame relay protocol processing section and the standby frame relay protocol processing section. it can.

(4) When switching from the active system frame relay / protocol processing unit to the standby system frame relay / protocol processing unit in response to an instruction to switch the active protection from the control unit, the active system frame relay / protocol processing unit May include a step of transferring a frame identifier indicating completion of frame assembly to the standby frame relay protocol processing unit when the cell data added with the copy indication is assembled into a frame and transmitted.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is an explanatory diagram of a system configuration of an embodiment of the present invention, showing a main part of a frame relay switch, 1 is a time division switch part, and 2-1 to 2-n are frame relays. Protocol processing unit, 3 multiplexing unit, 4 cell switching unit, 5 relay line unit, 6 frame processing unit, 7
Is a control unit, 8 is a subscriber terminal device, 9 is a cell-frame conversion unit, 10 is a logical-physical conversion table, and 11a and 11b.
Is a cell data to which a copy display is added, and 12 is a copy display identification part (*).

The frame relay exchange has a structure similar to that of the conventional example shown in FIG. 4, and N of the frame relay protocol processing units 2-1 to 2-n are used as an active system and M as a standby system. Further, the logical-physical conversion table 10 is
A physical number assigned to the frame relay / protocol processing units 2-1 to 2-n and a frame relay / protocol processing unit 2-1 for demultiplexing and distributing cell data from the multiplexing unit 3.
Is a table showing corresponding to the logical numbers of ~ 2-n,
By rewriting the logical number under the control of the control unit 7, the frame relay protocol processing unit for transferring the demultiplexed cell data can be designated.

The frame relay protocol processing unit 2-
1 to 2-n include a cell-frame conversion unit 9, a copy display identification unit 12, and the like. The cell-frame conversion unit 9 adds a frame identifier to frame data and decomposes the data to divide it into 48 bytes, for example. Then, a header portion of 5 bytes is added to it to form a cell, and the function of transmitting this cell data and the header portion of the cell data and the frame identifier or copy display are removed and assembled to form a frame, and this frame data is transmitted. It has a function. Further, the copy display identification unit 12 identifies the copy display added to the cell data. The function of the copy display identification unit 12 can be provided in the cell-frame conversion unit 9.

In normal operation, the cell data input via the relay line section 5 and the cell switch section 4 is demultiplexed in the multiplexing section 3 to obtain the logical-physical conversion table 1.
With reference to the contents of 0, the cell data is transferred to the frame relay protocol processing unit. Copy display is not added to the cell data in that case.
Copy display identification unit 1 of protocol processing units 2-1 to 2-n
2 will not work.

The frame relay / protocol processing unit of the switching source is changed from the control unit 7 to the frame relay / protocol processing unit of the active system by the fault, the maintenance, the normality confirmation of the standby system, or the like.
An active spare switching instruction designating the switching destination frame relay protocol processing unit is added to the multiplexing unit 3, and the logical-physical conversion table 10 is rewritten. Thereby, of the cell data demultiplexed in the multiplexing unit 3, the cell data to be transferred to the switching source frame relay / protocol processing unit, which is the active system, is copied, and the switching destination frame relay that is the standby system is copied. -Transfer also to the protocol processing unit. In that case, a copy display is added to the cell data transferred to the switching source and switching destination frame relay protocol processing units.

The cell data to which the copy display is added is identified by the copy display identification unit 12 of the frame relay protocol processing unit, and the cell-frame conversion unit 9 of the active frame relay protocol processing unit When one frame is assembled by the cell data to which the copy display is added, the conversion of the subsequent cell data to the frame data is stopped, and the cell-frame conversion unit 9 of the standby frame relay protocol processing unit displays the copy display. When one frame is assembled by the cell data to which is added, a frame in which the subsequent cell data is assembled is transmitted, and the data up to that point is discarded. Then, the logical-physical conversion table 10 is rewritten, and the frame relay / protocol processing unit that has been the active system up to that point becomes the standby system, and the frame relay / protocol processing unit that has been the standby system until then becomes the active system. .

The copy display is, for example, 5 ATM cell.
The virtual path identifier (VPI) and virtual channel identifier (VCI) in the header part of the byte are used, or the spare type of the payload type (PT) is used, or added in the frame relay switch. One byte of additional data can be used. Then, when the same cell data is transferred to the active system and the standby system, copy display is added.

The copy display identification section 12 extracts and identifies the header portion or additional data of the cell data to which the copy display is added, and the cell-frame conversion section 9
Separates the header part and the data part of the cell data, or separates the additional data from the data part when there is additional data, and assembles the data part to form a frame. It is possible to identify whether or not the copy display is added by using the header portion or the additional data.

FIG. 2 is a sequence diagram for explaining the embodiment of the present invention, in which the control unit 7, the relay line unit 5, and the multiplexing unit 3 are used.
And the frame relay protocol processing units 2-1 to 2-n
Of the active and standby systems, the frame processing unit 6 and the subscriber terminal device 8 of the frame relay protocol processing unit 2
-1 to 2-n are displayed as processing units.

The control unit 7 is used to switch the active spare.
Causes the frame processing unit 6 to temporarily stop the frame data input from the subscriber terminal device 8 to the frame relay protocol processing unit via the time division switch unit 1. In that case, it is also possible to control so that only the frame data to be input to the switching source frame relay protocol processing unit of the active system is temporarily stopped.

Then, the control section 7 instructs the multiplexing section 3 to
A switching instruction including the physical number of the switching source frame relay protocol processing unit of the active system and the physical number of the switching destination frame relay protocol processing unit of the standby system is added. As a result, the setting of the logical-physical conversion table 10 of the multiplexing unit 3 and the setting of copy display are performed.

For example, when switching from the active frame switching source frame relay protocol processing unit 2-2 to the standby system switching destination frame relay protocol processing unit 2-n, the contents of the logical-physical conversion table 10 are: As shown in (a) of FIG. 3, logical numbers are set for the physical numbers 0 to n−1. For example, the logical number of the frame relay protocol processing unit 2-2 with the physical number 1 is 5, Physical number n-1
When the logical number of the frame relay / protocol processing unit 2-n is set to 8, the physical-logical conversion table 10 is changed to the physical-logical conversion table 10 by the switching instruction from the control unit 7.
As shown in, the logical number of the frame relay protocol processing unit 2-n of the switching destination of the standby system is rewritten to 5 which is the same as the logical number of the frame relay protocol processing unit 2-2 of the switching source of the active system. .

As a result, the data is input to the multiplexing unit 3 via the relay line unit 5 and the cell switch unit 4 and is demultiplexed. For example, the contents of the logical-physical conversion table 10 shown in FIG. The cells 1 to n corresponding to the logical number 5 are the physical number 1 of the active system and the physical number n-1 of the standby system.
Of the frame relay protocol processing units 2-2 and 2-n. At this time, due to the presence of the switching instruction or the same logical number, the copy display is added to the cell data distributed to the plurality of frame relay protocol processing units as indicated by the black circles in FIG.

When the cell-frame conversion unit 9 identifies a copy display by the function of the copy display identification unit 12, it removes the copy display and assembles the cell data into a frame. The active frame relay protocol is used. When the frame assembly is completed, the processing unit 2-2 receives the frame 1
Is sent to the subscriber terminal device 8 via the time division switch unit 1. In that case, the frame relay / protocol processing unit 2-n of the standby system also identifies the cell data to which the copy display is added by the copy display identification unit 12 and displays the copy display when the cell-frame conversion unit 9 assembles it into a frame. Is to be removed.

The frame relay protocol processing unit 2-2 of the active system assembles the cell data to which the copy display is added into a frame, so that the frame relay protocol processing unit 2-n of the standby system is shown in the figure. A frame identifier indicating the completion of the assembly of one frame is transferred by the omitted path, and the frame relay protocol processing unit 2-n of the standby system is transferred.
Responds to this with an OK / NG response indicating whether frame assembly is normally performed. If an OK response is sent, the frame data assembled up to that point is discarded and the frame data is assembled after that. The frame data is sent to the subscriber terminal device 8 via the time division switch unit 1.

The active frame relay protocol processing section 2-2 releases the internally held data by receiving an OK response from the standby frame relay protocol processing section 2-n, and when the NG response is received, Frame data is set based on the internally held data, and when one frame is assembled, the frame data is sent to the subscriber terminal device 8 side. That is, this corresponds to a case in which a failure is latent in the frame relay protocol processing unit 2-n of the standby system of the switching destination and the switching of the active standby fails, and it is possible to switch back to the active system.

When an OK response is received from the standby frame relay protocol processing unit 2-n and the internally held data is released, a response indicating that the internally held data is released is transmitted to the multiplexing unit 3, The multiplexing unit 3 sets the logical-physical conversion table 10 and cancels the copy display, and notifies the control unit 7 of that as a response. That is, the contents of the logical-physical conversion table 10 are rewritten as shown in (b) to (c) of FIG. 3, and the frame relay protocol processing unit 2-2 of the physical number 1 which has been the active system until now is The frame relay / protocol processing unit 2-n having the logical number 8 belonging to the standby system and the physical number n-1 which has been the standby system until now is
The logical number is 5 which belongs to the active system. As a result, the active system is switched to the standby system, and the standby system is switched to the active system. Further, by releasing the copy display, the multiplexing unit 3 transfers the cell data by the normal demultiplexing to the frame relay protocol processing unit which has become the active system.

Then, the control unit 7 includes the time divisional switch unit 1
Of the path setting between the subscriber terminal device 8 and the frame relay protocol processing unit 2-2 of the active system up to now, and the frame relay protocol processing unit 2-n of the standby system up to now. To the frame processing unit 6, and the frame relay / protocol processing unit 2-n switched from the standby system to the active system uses the following cells 1 to 1 The frame 2 assembled by n is sent to the subscriber terminal device 8 via the time division switch unit 1. Through the above processing steps, the control unit 7 finishes the switching processing of the working spare.

In the above sequence explanatory diagram, the case where the assembly of one frame is completed by the cells 1 to n, the timing of the switching instruction from the control unit 7 is the cells 1 to 1 constituting one frame. It can be an arbitrary position of the cell n. For example, when the switching instruction is issued at the reception timing of the cell 10, a copy display is added to the cell data of the cell 11 and subsequent cells, and the active frame relay protocol processing section and the standby frame relay protocol processing section are connected. And the frame is assembled,
Since the active frame relay protocol processing unit has already received cells 1 to 10 to which the copy display is not added, reception of cell n completes the assembly of one frame by cells 1 to n. , The frame data is sent to the subscriber terminal device 8 side as before.

On the other hand, in the standby frame relay protocol processing section, cells 11 to n to which copy indication is added are added.
, The cell 1 to the cell 10 are insufficient, so that the assembly of one frame is not completed. Therefore, the standby system frame relay protocol processing unit transmits to the active system frame relay protocol processing unit. The frame identifier indicating the completion of frame assembly is not transferred, and the data in this case is discarded. In this case, for example, the payload type (PT) of the header part of the cell data is used to indicate whether it is the first cell data or the last data, or the segment type (ST) and the sequence number (S).
N) is added to the cell data, it is possible to identify whether or not the cell data is the head cell data of the frame. Therefore, if the cell data at the head of this frame is not received, the cell data received after that is discarded. be able to.

By receiving the cells 1 to n to which the next copy indication is added, the active frame relay protocol processing section sends the assembled frame data to the subscriber terminal device 8 side. Further, since the assembly of one frame can be completed even in the standby frame relay protocol processing section, the frame identifier indicating the frame assembly completion is transferred to the active frame relay protocol processing section, and the frame data is transferred. Discard. Then, the standby system frame relay protocol processing section receives the next cell 1 to cell n, validates the assembled frame data, and sends the frame data to the subscriber terminal device 8 side.

Further, when the active frame relay protocol processing section receives the frame identifier indicating the completion of frame assembly from the standby frame relay protocol processing section,
Discard cell data during frame assembly. In other words, the active frame relay protocol processing unit stops the processing of cell data into frames and frame data into cells. Therefore, even if an instruction to switch the active spare is sent from the control unit 7 at an arbitrary timing, the active spare can be switched without losing data.

[0034]

As described above, according to the present invention, N: M
Frame protection / protocol processing unit 2 of the current spare configuration
In the active standby switching of -1 to 2-n, the same frame-copy protocol processing unit of the switching system of the active system and the frame relay protocol processing unit of the switching system of the standby system are added with the same copy display. When the cell data is input and the frame assembly is completed, the frame relay protocol processing section of the standby system switching destination starts sending the assembled frame data, and the active system switching source frame relay protocol processing is started. The part is a spare system, and it is possible to switch the working spare without loss of transfer data, and even if the switching fails, switch back to the working system.
There is an advantage that the transmission of frame data can be continued. Further, since it is possible to control the switching of the working spare by only the control processing in the own frame relay switch, there is an advantage that the working spare can be switched without being affected by the network configuration.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a system configuration according to an embodiment of the present invention.

FIG. 2 is a sequence explanatory diagram of the embodiment of the present invention.

FIG. 3 is an explanatory diagram of a logical-physical conversion table according to the embodiment of this invention.

FIG. 4 is an explanatory diagram of a system configuration.

[Explanation of symbols]

 1 time division switch unit 2-1 to 2-n frame relay / protocol processing unit 3 multiplexing unit 4 cell switch unit 5 relay line unit 6 frame processing unit 7 control unit 8 subscriber terminal device 9 cell-frame conversion unit 12 copy Display identification section

Claims (4)

[Claims] 1. A method for switching an active protection of a frame relay protocol processing unit for converting cell data into frames and converting the frame data into cells, wherein an active system frame relay protocol processing unit and a backup are instructed by a switching instruction of the active backup. The cell data to which the copy display is added is transferred to both the system frame relay protocol processing unit, and when the frame assembly by the cell data to which the copy display is added is completed, the active system frame relay protocol processing unit And a standby switching method for active use, comprising a step of switching processing operations between the standby system frame relay protocol processing section. 2. A plurality of frame relay / protocol processing units, each of which is composed of a plurality of active systems and an arbitrary number of standby systems, forms cell data into frames, and converts the frame data into cells, and an exchange connection of the frame data. The frame of the frame relay switch having a time division switch unit for performing, a multiplexing unit for multiplexing and demultiplexing the cell data, a cell switch unit for performing an exchange connection of the cell data, and a control unit for controlling each unit. In the active standby switching method of the relay / protocol processing unit, in response to a switching instruction of the active standby from the control unit, the multiplexing unit adds a copy display to the cell data, and the active frame relay protocol processing unit and Transfer to both the standby system frame relay / protocol processing unit, and the working system frame relay / protocol processing unit copies After sending the cell data assembly completed frame to which the indication is added to the subscriber terminal device through the time division switch unit, the processing is stopped, and the standby frame relay protocol processing unit displays a copy display. An active backup switching method comprising the steps of discarding an assembly completion frame of the added cell data and sending a frame assembled after the frame to the subscriber terminal device via the time division switch unit. 3. The control unit includes a logical-physical conversion table in which a logical number of demultiplexed cell data and a physical number of a frame relay protocol processing unit for transferring the cell data are associated with each other. A logical number corresponding to the physical number of the active system frame relay / protocol processing unit in the logical-physical conversion table and a logical number corresponding to the physical number of the standby system frame relay / protocol processing unit in accordance with a switching instruction of the active spare from the unit. And a copy indication is added to the cell data according to the logical number, and the cell data is transferred to both the active frame relay protocol processing section and the standby frame relay protocol processing section. 3. The active backup switching method according to claim 1, wherein: 4. The active frame relay / protocol processing unit when switching from the active frame relay / protocol processing unit to the standby system frame relay / protocol processing unit in response to an active / standby switching instruction from the control unit. The method includes a step of transferring a frame identifier indicating completion of frame assembly to the standby frame relay protocol processing unit when cell data with copy indication added is assembled and transmitted to a frame. The active standby switching method according to any one of 1 to 3.