KR100423488B1 - Redundancy Structure of Interprocessor Communication Network in Switching System - Google Patents

Abstract

The present invention relates to a duplex structure of an interprocessor communication network in a switching system, and more particularly, to a main switching device and a sub switching device that switch data paths when data is transmitted and received between processors in an interprocessor communication network. The present invention relates to a duplex structure of a communication network between processors in an exchange system that enables smooth data transmission and reception between processors even when a defect occurs.

In a conventional processor-to-processor duplex structure, when a defect in the inter-processor communication network occurs due to damage of the main switching device or the sub-switching device, data transmission through the corresponding main switching device or the sub-switching device is impossible. There was a problem that data transmission and reception could not be performed.

The present invention is to duplicate the main switching device and the sub-switching device of the inter-processor communication network to perform independent operation so that even if a defect occurs in one main switching device or sub-switching device, another main switching device or sub-switching in which the defect does not occur. Since the device performs a data transmission / reception operation, there is an advantage of enabling stable data transmission and reception between processors.

Description

Dual Architecture of Interprocessor Communication Network in Switching System

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a duplex structure of an interprocessor communication network in a switching system, and in particular, a main switching device and a sub switching a path of data when data is transmitted and received between processors in an interprocessor communication network. (Sub) The present invention relates to a duplex structure of a communication network between processors in a switching system that enables smooth data transmission and reception between processors even when a defect occurs in a switching device.

In general, an inter-processor communication network performing data transmission / reception between a plurality of processors is a main that forms an inter-processor communication network between sub-switching devices by connecting a plurality of sub-switching devices in a hub form as shown in FIG. 1. A switching device, a sub-switching device connected to a plurality of processors to form an inter-processor communication network between the processors, and a plurality of processors for transmitting and receiving data in a high-level data link control procedure (HDLC) frame. However, in a general inter-processor communication network, when a defect in the inter-processor communication network occurs due to damage of a data transmission cable installed between the main switching device and the sub-switching device, the data transmission and reception between the processors cannot be performed smoothly.

As such, in order to perform smooth data transmission and reception between processors even when a defect occurs on the data transmission cable between the main switching device and the sub-switching device, an interprocessor communication network having a redundant structure as shown in FIG. 2 is conventionally implemented. As shown in FIG. 2, the redundant structure of the inter-processor communication network shows a part of the inter-processor communication network formed by connecting the main switching device, one sub-switching device, and one processor in FIG. 1. It comprises a switching unit 18 and the main node (16, 17), the sub-switching device comprises a gateway 14, 15 and the sub-switching unit 13, the processor is a redundant processor 11, 12) is made, including.

The main switching unit 18 switches a data communication path between processors by switching a path of data input and output through the main nodes 16 and 17. The main nodes 16 and 17 operate in a duplexing manner of an active or standby mode to match data transmitted through the main switching unit 18 to a data transmission cable, and to transfer the redundant data of the active or standby mode. The data transmitted from the gateways 14 and 15 operating in the manner is matched to the main switching unit 18 and transmitted.

The gateways 14 and 15 operate in a redundant manner of operation or standby mode to match data transmitted from the sub-switching unit 13 with data transmission cables, and transmit the data transmitted from the main nodes 16 and 17. Match with the switching unit 13 and transmit. The sub-switching unit 13 switches the data transmission path input and output between the processors 11 and 12 and the gateways 14 and 15.

The processors 11 and 12 operate in a redundant manner in an operation or standby mode, and are connected to a sub-switcher 13 by a data bus to transmit and receive data in an HDLC frame.

Referring to FIG. 2, the operation of the redundant structure in the conventional inter-processor communication network configured as described above is as follows.

The processors 11 and 12, the gateways 14 and 15, and the main nodes 16 and 17 of the inter-processor communication network have a characteristic of being operated in a redundant manner of operation or standby mode. For example, the processor 11 operates. In the active mode, the processor 12 operates in the standby mode, and when the processor 12 is in the operating mode, the processor 11 operates in the standby mode and operates in the operating mode. Data is transmitted and received by (12). Accordingly, the processor 11, the gateway 14, and the main node 16 operate in the operation mode and the processor 12, the gateway 15, and the main node 17 enter the standby mode on the data transmission path of the interprocessor communication network. In the case of assuming that the data transmission operation is assumed, the processor 11 in the operation mode transmits data to the sub-switching unit 13 in the HDLC frame, and the sub-switching unit 13 transmits the data received from the processor 11. Is transmitted to the gateway 14 in the operation mode, and the gateway 14 matches the data received from the sub-switching unit 13 to the data transmission cable and transmits the data to the main node 16 in the operation mode. In addition, the main node 16 matches and transmits data transmitted from the gateway 14 to the main switching unit 18, and the main switching unit 18 transmits the path of the data transmitted from the main node 16 to the other party's purpose. Connect to the processor side.

On the other hand, when data is transmitted from the counterpart target processor side of the interprocessor communication network to the main switching unit 18, the main switching unit 18 transmits the data transmitted from the counterpart processor side to the main node 16 in the operation mode. In addition, the main node 16 matches the data transmitted from the main switching unit 18 to the data transmission cable and transmits the data to the gateway 14 in the operation mode, and the gateway 14 transmits the data received through the data transmission cable. The sub-switching unit 13 matches and outputs the sub-switching unit 13, and the sub-switching unit 13 transmits the data received from the gateway 14 to the processor 11 operating in the operation mode, whereby the processor of the inter-processor communication network in the switching system. Allows you to perform data transmission and reception between them.

As described above, in the conventional switching system, the duplex structure of the inter-processor communication network realizes duplication of the data transmission cable by duplication of the main nodes 16 and 17 and the gateways 14 and 15, thereby transferring data connected to the main nodes 16 and 17. Even if a defect occurs in the inter-processor communication network due to the damage of the cable or the data transmission cable connected to the gateways (14, 15), another data transmission cable that does not cause damage can be used to smoothly transmit and receive data between the processors. Can be.

However, in the conventional switching system as described above, the duplex structure of the inter-processor communication network causes the failure of the inter-processor communication network due to the damage of the main switching device or the sub-switching device. Since transmission was impossible, there was a problem that data transmission and reception between processors could not be performed.

The present invention has been made to solve the problems described above, even if the main switching device and the sub-switching device of the inter-processor communication network to operate independently, even if a defect occurs in one main switching device or sub-switching device. It is an object of the present invention to smoothly transmit and receive data between processors by performing data transmission / reception using another main switching device or sub-switching device in which a defect does not occur.

Features of the present invention for achieving the above object, the first and second main switching device for switching the data transmission path input and output between the sub-switching device to be redundant to perform the independent operation, and to perform the independent operation First and second sub-switching devices for switching the data transmission path input and output between the processor and the main switching device; It is provided with a first processor and a second processor for transmitting and receiving data through a cable with the first and second sub-switching device by operating in a redundant manner of operation / standby mode.

1 is a block diagram of an interprocessor communication network in a general switching system;

2 is a block diagram of a redundant structure of an interprocessor communication network in a conventional switching system;

3 is a block diagram illustrating a duplex structure of an interprocessor communication network in an exchange system according to an embodiment of the present invention;

Explanation of symbols on the main parts of the drawings

11, 12, 21, 22: processor 30, 40: sub-switching device

50,60: main switching device 31,41: subnode

13,32,42: Sub switching unit 14,15,33,43: Gateway

16, 17, 51, 61: main node (18, 52, 62): main switching unit

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

The redundant structure in the inter-processor communication network according to the embodiment of the present invention includes a main switching device (50, 60), a sub-switching device (30, 40) and the processor (21, 22) as shown in FIG. Is done.

The main switching devices 50 and 60 switch the transmission path of data input / output between a plurality of sub-switching devices by duplexing the conventional main switching device of FIG. 2 to perform independent functions, and the main switching unit. (52, 62) and main nodes (51, 61).

The main switching units 52 and 62 operate in an active mode to switch data transmission paths between the processors of the inter-processor communication network by switching the paths of data input and output through the main nodes 51 and 61 and internally. If a fault occurs, a data transmission failure signal is generated and output. The main nodes 51 and 61 operate in the operation mode, and match the data transmitted through the main switching units 52 and 62 to the data transmission cables and transmit them to the gateways 33 and 43, and from the gateways 33 and 43, The data to be transmitted is matched to the main switching units 52 and 62 and transmitted.

On the other hand, the sub-switching devices 32 and 42 duplicate the conventional sub-switching device of FIG. 2 to perform independent functions to switch the transmission path of data input / output between the processor and the main switching device, and the gateway 33 And 43, the sub-switching parts 32 and 42 and the sub nodes 31 and 42.

The gateways 33 and 43 operate in the operation mode to match the data transmitted from the sub-switching units 32 and 42 to the data transmission cable and transmit the data to the main nodes 51 and 61, and from the main nodes 51 and 61. The data transmitted through the data transmission cable is matched to the sub switching units 32 and 42 and output. The sub-switching units 32 and 42 operate in an operation mode to switch input / output data paths between the gateways 33 and 43 and the subnodes 31 and 41, and when a self-internal fault occurs, the data transmission failure signal is transmitted. Create and print

The sub-nodes 31 and 41 operate in the operation mode, match the data transmitted from the sub-switching units 32 and 42 to the data transmission cable, and transmit the data to the processors 21 and 22 that operate in the redundant mode of operation or standby mode. The data transmitted from the processors 21 and 22 are matched to the sub-switching units 32 and 42 and transmitted.

The processors 21 and 22 operate in a redundant manner in an operation or standby mode to transmit and receive data in the HDLC frame format with the subnodes 31 and 41.

An operation of the redundant structure of the interprocessor communication network in the switching system according to the present invention configured as described above will be described with reference to FIG.

In the redundant system of the inter-processor communication network in the switching system according to the present invention, the main switching units 52 and 62, the main nodes 51 and 52, the gateways 33 and 43, the sub-switching units 32 and 42, The subnodes 31 and 41 are operated in an operation mode (Active), while the processors 21 and 22 are operated in a redundant manner of an operation or standby mode (Active / Standby).

Assuming that the processor 21 operates in the operation mode and the processor 22 operates in the standby mode in such an inter-processor communication network, transmission and reception of data is performed by the processor 21 operating in the operation mode. The data output from 21 is transmitted to the sub node 31 and the sub node 41, and the sub node 31 matches the data transmitted from the processor 21 to the sub switching unit 32 and then the sub switching unit. And the sub node 41 matches the data received from the processor 21 to the sub-switching unit 42, and then the gateway 43 through the sub-switching unit 42. To send.

Then, the gateway 33 matches the data transmitted from the sub node 31 through the sub switching unit 32 to the data transmission cable, and then transmits the data to the main node 51 and the main node 61, and the gateway 43 ) Matches the data transmitted from the sub node 41 through the sub switching unit 42 to the data transmission cable and transmits the data to the main node 51 and the main node 61.

However, when a defect occurs in the sub-switching unit 32 or the sub-switching unit 42 and the data transmission operation cannot be performed, the corresponding sub-switching unit 32 or the sub-switching unit 42 in which the defect has occurred transmits the data. The fault signal is generated and applied to the main node 51 and the main node 61 through the gateway 33 or the gateway 43.

Accordingly, the main node 51 and the main node 61 are data transmission cables connected to the gateway 33 and the gateway 43 when the normal data is transmitted from the gateway 33 and the gateway 43 through the data transmission cable. Select one of them to receive data. If a data transmission failure signal is applied from the gateway 33 or the gateway 43 through the data transmission cable, select a data transmission cable to which the failure signal is not applied. Receive.

Thereafter, the main node 51 matches and transmits data transmitted from the gateway 33 or the gateway 43 to the main switching unit 52, and the main switching unit 52 transmits data transmitted from the main node 51. Connect the path of to the destination processor side. In addition, the main node 61 matches and transmits data transmitted from the gateway 33 or the gateway 43 to the main switching unit 62, and the main switching unit 62 transmits data transmitted from the main node 61. Connect the path of to the destination processor side.

On the other hand, when data is transmitted from the counterpart target processor side to the main switching unit 52 and the main switching unit 62 operating in the operation mode, the main switching unit 52 receives the data received from the counterpart target processor side of the main node. At step 51, the main switching unit 62 applies the data received from the counterpart target processor to the main node 61. At this time, the main node 51 matches the data transmitted from the main switching unit 52 to the data transmission cable, and then transmits the data to the gateway 33 and the gateway 43, and the main node 51 is the main switching unit 52. After transmitting the data transmitted from the) to the data transmission cable and transmits to the gateway 33 and the gateway 43.

However, when a defect occurs in the main switching unit 52 or the main switching unit 62 so that normal data transmission cannot be performed, the main switching unit 52 or the main switching unit 62 in which the defect occurs has a data transmission failure signal. When the main switch unit 52 generates a fault signal, the fault signal is applied to the gateway 33 and the gateway 43 through the main node 51, and the main switch unit 62 is generated. When the data transmission failure signal is generated, the failure signal is transmitted to the gateway 33 and the gateway 43 through the main node 61.

Accordingly, when the normal data is transmitted from the main node 51 and the main node 61 through the data transmission cable, the gateway 33 and the gateway 43 randomly select one of the corresponding data transmission cables to receive the data. When the data transmission failure signal is applied from the main node 51 or the main node 61 through the data transmission cable, the data transmission cable to which the corresponding failure signal is not applied is selected to receive data. At this time, the gateway 33 matches and outputs the data received from the main node 51 or the main node 61 to the sub-switching unit 32, and the sub-switching unit 32 transmits the data transmitted from the gateway 33. Is applied to the subnode 31.

The gateway 43 matches the data received from the main node 51 or the main node 61 to the sub-switching unit 42 and outputs the data. The sub-switching unit 42 transmits the data transmitted from the gateway 43. Is applied to the subnode 41.

On the other hand, the sub-node 31 matches the data received from the gateway 33 through the sub-switching unit 32 to the data transmission cable and transmits the data to the processor 21 or the processor 22 operated in the operation mode. The sub node 41 transmits the data received from the gateway 43 through the sub switching unit 42 to the data transmission cable and transmits the data to the processor 21 or the processor 22 operating in the operation mode.

Accordingly, assuming that the processor 21 of the processor 21 and the processor 22 is operated in the operation mode, and the processor 22 is operated in the standby mode, the processor 21 operating in the operation mode includes the subnode ( 31) and when normal data is transmitted from the sub node 41 through the data transmission cable, one of the data transmission cables is arbitrarily selected to receive data, and the data is received from the sub node 31 or the sub node 41. When a data transmission failure signal is applied through a transmission cable, a data transmission cable that is not applied with the failure signal is selected to receive data, thereby performing a stable data transmission / reception operation between processors in a processor-to-processor communication network in a switching system.

As described above, the present invention is to duplicate the main switching device and the sub-switching device of the inter-processor communication network to perform independent operation, so that even if a defect occurs in one main switching device or a sub-switching device, another main which does not have a defect occurs. Since a data transmission / reception operation is performed by using a switching device or a sub-switching device, there is an advantage of enabling stable data transmission and reception between processors.

Claims (4)

In the redundant structure of the inter-processor communication network in the switching system, It is duplexed to perform independent operation and switches the data transmission path input / output between sub-switching devices, and matches the main switching unit that generates and outputs a fault signal when its internal defect occurs, and the data input / output through a plurality of cables. First and second main switching devices including main nodes configured to check whether a failure signal exists in each data and to selectively receive and match data for which the failure signal has not occurred; A sub-switching unit which is duplexed to perform independent operation and switches a data transmission path input / output between the processor and the main switching device and generates and outputs a failure signal when an internal defect occurs, and data input / output to the main switching device And a gateway for selectively receiving and matching data in which the failure signal does not exist by matching each other with each other, and connecting the sub-switching unit to the processor through a plurality of cables. First and second sub-switching devices having sub-nodes for matching data inputted and outputted; And a first processor and a second processor operating in a duplex mode of an operation / standby mode to transmit and receive data to and from the first and second sub-switching devices via a cable. The method of claim 1, When the processor receives data applied through a cable connected to the first and second sub-nodes, the processor randomly selects a cable to which a failure signal is not applied and receives the data. The redundant structure of the inter-processor communication network in the switching system, characterized in that for receiving the data by selecting the cable to which the failure signal is not applied. The method of claim 1, When the main node matches data applied through a cable connected to the first and second gateways, the main node arbitrarily selects a cable to which a failure signal is not applied and matches the received data. And, if the failure signal is not applied, selects a cable to which data is received to match the received data. The method of claim 1, When the gateway matches data applied through a cable connected to the first and second main nodes, the gateway randomly selects a cable to which a failure signal is not applied and matches the received data. And, if the failure signal is not applied, selects a cable to which data is received to match the received data.