KR100418342B1 - Redundant transfer method by power off in exchange - Google Patents

Abstract

The present invention relates to redundancy switching by power-off in an exchange. Particularly, in redundancy switching by power-off between processors implemented in redundancy, in an exchange where power switching operation is performed after the data that is being processed is completely transferred to the standby side. The present invention relates to a redundant switching method by powering off.

According to the present invention, when the switching is performed by the power-off at the exchange, the active data is completely transmitted to the standby side-side redundancy control unit under the control of the magnetic-side redundancy control unit when the active side power supply is turned on. By turning off the power of the side side power supply to operate the standby side as an active side, it is possible to prevent data loss during redundancy switching, and to enable stable system operation and redundancy switching.

Description

Redundant transfer method by power off in exchange

The present invention relates to redundancy switching by power-off in an exchange. Particularly, in redundancy switching by power-off between processors implemented with redundancy, the power is switched in a switch to perform a power switching operation after completely transmitting active information to the standby side. It relates to a redundant switching method by turning off.

In a conventional exchange, a redundant switching device by powering off is configured as shown in FIG.

A power supply unit 10a, 10b, a plurality of functional units 20a to 20n, 30a to 30n, and redundant control units 40a and 40b are provided on each side of the exchanger system operated in redundancy.

The power supply units 10a and 10b supply power to the multiple functional units 20a to 20n, 30a to 30n and the redundancy control units 40a and 40b on the side of their own side, and provide a power supply stop signal at both sides when redundancy is switched. It applies to the duplication control part 40a, 40b side.

The redundancy control unit 40a or 40b controls redundancy of the multiple functional units 20a to 20n, 30a to 30n mounted on the side of the magnetic side, so that a power supply stop signal is applied from the power supply units 10a and 10b. The redundant data is transmitted and received to the opposite side.

Referring to the redundant switching operation by the power-off in the conventional exchanger configured as described above in detail as follows.

During the operation of the exchange system, it is operated in redundancy for stability and reliability.If an error occurs in the side that is active while the system is in operation, or if you want to switch the side to the standby state to replace or check the functional part of the side. In this case, there is a switching method by switching off the power supply of one of several switching methods.

It is assumed that a plurality of functional units 20a to 20n are mounted on the A side shown in FIG. 1 and operate in an active state, and a plurality of functional units 30a to 30n are mounted on the B side to operate in a standby state. Next, the redundant switching operation by turning off the power will be described.

First, when an abnormality occurs during operation of the A side in an active state, or when the A side is to be switched to a standby state for replacement or inspection of the functional part, the power supply part 10a of the A side has a large number of functional parts on its own side. The power is supplied to the 20a to 20n and the redundancy control unit 40a, which is supplied to the first redundancy control unit 40a on the side where the magnet is mounted and the second redundancy control unit 40b mounted on the B side during redundancy switching. The power supply stop signal is applied to indicate that the magnetic power is turned off.

Then, the first redundancy control unit 40a of the A side detects that the power is turned off after a predetermined time according to the power supply stop signal applied from the power supply unit 10a of the side on which the magnet is mounted, and the magnet is mounted on the side. The data being processed is received from the functional units 20a to 20n, and is transferred to the second redundancy control unit 40b on the B side in the standby state.

At this time, the first power supply unit 10a of the A side in the active state stops the actual power supply after about 500 mSec for a predetermined time after outputting the power supply stop signal, and the first redundancy control unit of the A side for about 500 msec ( 10a) controls the corresponding functional units 20a to 20n, and continuously transmits data through the redundant channel to the second redundancy control unit 40b on the B side to continue the function of operating in the active state.

Therefore, the second redundancy control unit 40b on the B side in the standby state transfers the data applied from the first redundancy control unit 40a on the opposite side to the functional units 30a to 30b, and after a predetermined time passes, the active state The in A side is powered off to stop active operation, and the opposing B side is operated in an active state.

However, when transferring data from the active side A to the standby side B, the data normally written to the memory on the side A in the active state is also written to the memory on the side B in the standby state. The data accumulated in the PC (Program Counter) value or the FIFO (First In Frist Out) of the sections 20a to 20n is not immediately written according to the amount of memory, and there is a time difference stored to some extent.

Therefore, there is a case where data of such a memory cannot be transferred within a predetermined time until the power of the A side in the active state is completely turned off.

As described above, when the active side switches the active state to the standby state by the power-off in the conventional exchange, the active side recognizes the power supply stop signal and transfers the memory data that was being processed on the standby side to the standby side. In this case, the power is turned off while the data is not transferred to the standby side exactly due to the amount of memory or the power off time irregularity. have.

The present invention has been made in view of the above-described problems, and in the case of redundancy switching by power-off in the exchanger, the standby side side redundancy under the control of the magnetic side redundancy control unit in the power-on state of the active side power supply unit After the data is completely transmitted to the control unit, the active side power supply is turned off to operate the standby side as the active side, thereby preventing data loss during redundancy switching, and providing stable system operation and redundancy switching. There is this.

1 is a block diagram showing a redundant switching device by the power off in the conventional exchange.

Figure 2 is a block diagram showing a redundant switching device by the power off in the exchange according to an embodiment of the present invention.

3 is a flow chart showing a redundant switching method by the power off in the exchange according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10a, 10b: power supply 20a-20n, 30a-30n: functional part

40a, 40b: redundant control unit

In order to achieve the above object, the present invention, in the redundant switching method by the power-off in the exchanger, if the power-off of the active side is required, the power supply of the active side of the active side and the standby side of the redundant Transmitting to the control unit; When the redundancy control unit on the active side receives the power-off request signal, transmits the data that is being processed for redundancy to the redundancy control unit on the standby side, and informs the completion of transmission of data required for redundancy switching when the transmission of the corresponding data is completed. Transmitting a redundancy completion signal for the redundancy control unit on the standby side; The redundant control unit on the standby side receives data necessary for the redundancy transfer from the redundancy control unit on the active side and transmits a power off control signal for turning off the power to the power supply unit on the active side when receiving the redundancy completion signal. Process; Generating a power supply stop signal for informing that the power supply is stopped when the power supply unit on the active side is powered off by a power off control signal and transmitting the generated power supply stop signal to a redundant control unit on the standby side; The standby control unit of the standby side characterized in that it comprises the step of operating by sensing the power supply stop signal.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Redundancy switching device by the power off in the switch according to an embodiment of the present invention, as shown in Figure 2, the power supply unit (10a, 10b) on each side in the switchboard system operating in redundancy, and a number of functions A part 20a-20n, 30a-30n, and the duplication control part 40a, 40b are provided.

The power supply unit 10a or 10b applies a power-off request signal for notifying that the power-off is required to the redundancy control units 40a and 40b of each side when redundancy switching by power off is required, and the redundancy control unit 40a After the power is turned off according to the power off control signal applied from 40b, the power supply stop signal is applied to the redundancy controllers 40a and 40b to indicate that the power is turned off.

The redundancy control section 40a, 40b controls the redundancy switching of the multiple functional units 20a-20n, 30a-30n mounted on the side of its own side, and responds to a power-off request signal applied from the power supply units 10a, 10b. Therefore, after the data being processed on the magnetic side required for the redundancy transfer is transmitted to the other side, the power supply control unit 10a, 10b applies a power off control signal to turn off the power. For example, the redundancy control unit on the A side side. When the power-off request signal is generated at 40a, the redundancy control unit 40a receives the power-off request signal and transmits the data, which is being processed for redundancy, to the redundancy control unit 40b at the side B. When the transmission is completed, the redundancy completion signal is transmitted to the redundancy control unit 40b, and the redundancy control unit 40b on the B side side receives the redundancy completion signal after receiving the corresponding data. When power is turned off by sending a control signal for turning off the power to the power supply portion (10a) of the A-side side turning off the power supply to the power supply unit (10a).

On the other hand, the signal shown in Figure 2 will be described.

The power off request signal is a ready signal for redundancy switching due to power off, and in order to indicate that power off is required in the active side power supply units 10a and 10b when redundancy switching due to power off is required. Transmit to 40a and 40b.

The redundancy completion signal is a signal for notifying that the transfer of the data being processed on the active side required for redundancy switching has been completed, and the active side redundancy control units 40a and 40b receive a power off request signal and receive a standby side side redundancy control unit ( The data is transmitted to 40a and 40b, and upon completion of transmission of the data, the data is transmitted to the standby side side redundancy control units 40a and 40b.

The power-off control signal is transmitted to the active side power supply units 10a and 10b by the standby side side redundancy control units 40a and 40b to turn off the power of the active side power supply units 10a and 10b when data transmission is completed.

The power supply stop signal is a signal indicating that the power supply of the power supply is completed. Both sides of the power supply unit 10a, 10b on the active side are turned off by the power off control signal from the redundant control unit on the standby side. Is applied to the redundant control units 40a and 40b.

The board detachment alarm signal is a signal for notifying mounting of both side power supply units 10a and 10b, and is applied to the redundancy control units 40a and 40b on the opposite side from the side where the power supply units 10a and 10b are unmounted.

Referring to the redundant switching operation by the power-off in the exchange configured as described above in detail as follows.

In the accompanying drawings, a plurality of functional units 20a to 2On are mounted on the A side and operated in an active state, and a plurality of functional units 30a to 30n are mounted on the B side and operated in a standby state. In the state, the redundant switching operation by powering off will be described. First, the power supply unit 10a of the A side is supplying power to the plurality of functional units 20a to 20n and the redundancy control unit 40a on the side of the A side. When redundancy switching is performed by turning off the power to replace or check the functional unit, the power supply unit 10a of the A side is mounted on the first redundancy control unit 40a and the B side of the side where the magnet is mounted. A power off request signal for notifying that the power off is required is applied to the second redundancy control unit 40b.

Then, the first redundancy control unit 40a on the A side requests duplication switching to the plurality of functional units 20a to 20n according to the power off request signal applied from the power supply unit 10a on the side on which it is mounted. The second redundancy control unit 40b on the B side prepares for redundancy switching in accordance with the power-off request signal applied from the counterpart first power supply unit 10a (step S1).

Accordingly, the first redundancy control unit 40a on the A side transmits data required for redundancy transfer such as memory data and FIFO data processed on the A side to the second redundancy control unit 40b on the other side B through the redundancy channel. do.

Then, when the transmission of the data is correctly completed by the first redundancy control unit 40a of the A side, the second redundancy control unit 40b of the B side of the counterpart B receives a redundancy completion signal for informing that transmission of data required for redundancy is completed. ) Is transmitted to the (S2) step.

Accordingly, the second redundancy control unit 40b of the corresponding B side recognizes that data transfer is completed when the redundancy completion signal is received from the first redundancy control unit 40a of the corresponding A side, and the first power supply unit of the other side A side. The power-off control signal for turning off the power is sent to the 10a side, and the first power supply 10a on the A side in the active state is turned off (step S3).

Accordingly, when the power is turned off by applying the power-off control signal from the second redundancy controller 40b on the side B, the first power supply unit 10a on the side A includes a plurality of functional blocks mounted on its own side ( 20a to 20n) and the power applied to the first redundancy control unit 40a are stopped. At this time, a power supply stop signal is generated and applied to the second redundancy control units 40a and 40b on both sides to indicate that the power off is completed. .

Accordingly, the second redundancy control unit 40b on the side B receives the power supply stop signal from the first power supply unit 10a on the side A and performs the redundancy switching operation correctly to operate in an active state (step S4). .

If the power supply units 10a and 10b are mounted on one side, the board hernia alarm signal is transmitted to the counterpart redundancy control units 40a and 40b, so that the counterpart hernia alarm can be detected to determine whether a duplication alarm has occurred. do.

As described above, in the present invention, in the case of performing a redundancy switching by power-off at the exchange, the active side side power supply unit does not turn off the power supply of the active side side power supply after one-way transmission of redundant data to the standby side side for a predetermined time. In the state that the power supply is ON, under the control of the self-side redundancy control unit, after the data required for redundancy transfer is completely transmitted to the standby side-side redundancy control unit, the active side power supply is turned off to turn off the standby side. By operating on the active side, data loss is prevented during redundancy switching, and redundancy switching by power-off used when replacing or checking the board of the active side is stabilized.

As described above, according to the present invention, in the case of performing a redundancy transfer by turning off the power at the exchange, the redundant data is completely transferred to the standby side side redundancy control unit under the control of the magnetic side redundancy control unit when the active side power supply is turned on. After transmitting, by turning off the power supply of the active side side power supply to operate the standby side as the active side, there is an effect of preventing data loss during redundancy switching, enabling stable system operation and redundancy switching.

Claims (1)

In the redundant switching method by the power off in the exchanger, Transmitting a power-off request signal from the active side to the redundancy control unit on the active side and the standby side when the active side is powered off; When the redundancy control unit on the active side receives the power-off request signal, transmits the data that is being processed for redundancy to the redundancy control unit on the standby side, and informs the completion of transmission of data required for redundancy switching when the transmission of the corresponding data is completed. Transmitting a redundancy completion signal for the redundancy control unit on the standby side; The redundant control unit on the standby side receives data necessary for the redundancy transfer from the redundancy control unit on the active side and transmits a power off control signal for turning off the power to the power supply unit on the active side when receiving the redundancy completion signal. Process; Generating a power supply stop signal for informing that the power supply is stopped when the power supply unit on the active side is powered off by a power off control signal and transmitting the generated power supply stop signal to a redundant control unit on the standby side; And a step in which the standby control unit of the standby side detects the power supply stop signal to operate actively.