KR19980075969A - Redundancy device to solve the problem of IPC path - Google Patents

Abstract

The present invention relates to a redundancy device for solving the problem of the IPC path for the IPC data transmission path transmitted between the processors belonging to the INS, CCS and the processors belonging to the ASS, IPC data and PCM data between the INS and ASS By adding IPC alarm data to the optical fiber link used to transmit the data, the receiver can select the transmission link without error in consideration of the status of the transmitter IPC alarm, and the information on the transmitter IPC alarm can be selected. As the message switch is transmitted, the receiving side message switch selects the receiving IPC data so as to receive normal IPC data, so that the IPC path can be normally performed.

Description

Redundancy device to solve the problem of IPC path

The present invention provides an interprocessor communication between an access switching subsystem (hereinafter abbreviated as ASS) and an interconnection network subsystem (hereinafter abbreviated as INS) of an electronic switchboard. , Which refers to the redundancy device to solve the path problem, in particular, the time switch and central data link of ASS (abbreviated as TSL) and the spatial switch local of INS. The present invention relates to a redundancy device for solving a problem on an IPC path provided by a data link block (hereinafter, referred to as SSL).

In general, an electronic exchange includes an ASS and an INS, and a central control subsystem (hereinafter, abbreviated as CCS).

ASS is a subscriber and relay signal service matching (Local Service Interface: abbreviated as LSI), time switch, Frame Relay Handler, optical subscriber access device, various signaling devices, packet handler, etc. It performs most of call processing function, self operation and maintenance function, and if necessary, it has a horizontally distributed structure as it increases by ASS unit.

INS connects between ASS, or between ASS and CCS, and performs the function of generating and distributing system clocks by providing number translation, route control, space switch network control and network synchronizer. Fiber between INS and ASS It is connected to an external subscriber using a link or data link.

CCS is a device that performs overall operation and maintenance of the system, and performs network management, test and measurement, billing statistics, I / O device control, and dialogue with other systems.

As described above, each block having an IPC path between ASS and INS is composed of cross-duplexing in an electronic switch having ASS, INS, and CCS to provide an IPC path at the other side when a problem occurs at one side. Device.

The redundancy device to solve the problem of IPC path is divided into two types, ASS link is 2K and 4K. In case of 2K, IPC path is composed of cross duplication. In addition, the lower 2K link stage and the upper 2K link stage are composed of active / standby redundancy with each other and are substantially quadruple.

However, for communication between the processor of ASS and the processor of INS, the IPC path is composed of duplex and quadruple, so that the speech data and IPC data are loaded and received on the optical fiber link. By selecting the receiving fiber link by considering only the fiber link status without considering the IPC alarm, if there is alarm IPC data among the sending IPC data, PCM data is normally transmitted and received, but IPC communication is frequently failed. There was a problem.

Accordingly, the present invention has been made to solve the above problems, and the object is to transmit data using an optical fiber link between the SSL of the INS and the TSL of the ASS. An object of the present invention is to provide a redundancy device for solving a problem on an IPC path in which only an IPC data transmission link can be selected.

The present invention for achieving this object relates to a redundancy device for solving the problem on the IPC path for transmitting IPC data and IPC alarm data transmitted from the main processor through the IPC path, the IPC data transmitted from each processor is specified A message switch for switching to be transmitted to the processor; SSL receiving in the cross direction to duplicate the IPC data and the IPC alarm data transmitted from the message switch; A TSL for receiving the IPC data and the IPC alarm data transmitted from the SSL in cross duplication, and transmitting the IPC data and the IPC alarm data in the cross duplication to the receiving side message switch; Adding IPC alarm data to the fiber link existing in the cross direction between SSL and TSL allows the IPC path to travel in the normal direction.

1A and 1B are block diagrams of a redundancy apparatus for solving a problem on an IPC path according to the present invention.

Explanation of symbols for main parts of the drawings

1,3: INS2,4: ASS

10,20,70,80: 1st, 2, 3, 4 message switch

100,110,200,210: 1st, 2, 3, 4 message switch

30,40: 1,2 SSL50,60: 1,2 TSL

120,130,140,150: 1,2,3,4 SSL160,170,180,190: 1,2,3,4 TSL

The objects and features of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings.

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

1A is a configuration diagram of a redundancy apparatus for solving a problem on an IPC path when an ASS link is 2K according to the present invention, and includes INS 1 and ASS 2 and first, second, third and fourth message switches. 10, 20, 70, 80, first and second SSLs 30 and 40, and first and second TSLs 50 and 60, respectively.

The INS (1) connects the ASS (2) with each other or between the ASS (2) and the CCS (not shown), while generating and distributing the system clock with number translation, route control, space switch network control and network device. In this case, the first and second SSL 30 and 40 of the INS 1 and the first and second TSL 50 and 60 of the ASS 2 are connected to an external subscriber using an optical fiber link. do.

The ASS 2 includes a subscriber and a time switch, an optical subscriber access device, various signaling devices, a packet handler, and the like to perform most call processing functions and self operation and maintenance functions.

The first, second, third and fourth message switches 10, 20, 70 and 80 are present between the processors inside the INS 1 and the first and second SSL 30 and 40 and between the processors. IPC data to be transmitted to the specified processor to be transmitted, and between the processor inside the ASS (2) and the first and second TSL (50) (60), switching so that IPC data transmitted from the processor is transmitted to the specified processor do.

The first and second SSLs 30 and 40 receive IPC data and IPC alarm data transmitted from the first and second message switches 10 and 20 through a spatial switch central data link to receive the first and second TSLs. 50 to 60 in the cross direction.

The first and second TSLs 50 and 60 receive the speech data, the IPC data, and the IPC alarm data transmitted from the INS 1 and transmit them in the cross direction to the third and fourth message switches 70 and 80.

Referring to the redundant device for solving the problem on the IPC path of the present invention configured as described above in more detail as follows.

For example, when the IPS data is transmitted from the INS 1 to the ASS 2, the first and second message switches 10 and 20 inside the INS 1 are used to display the first and second SSL 30 ( If the paths of a2, b1, and b2 except for a1 are out of the IPC paths transmitted to 40), the first and second SSLs 30 receive the IPC data received through the a1 path and transmit the received IPC data through the optical fiber links of aa1 and aa2. 1,2 The IPC data is transmitted to the TSL 50, 60.

The second SSL 40 transmits the bad IPC data to the first and second TSLs 50 and 60 through the optical fiber links bb1 and bb2 because the IPC data received through the a2 and b1 paths is bad.

Here, the ASS (2) is used for the alarm transmission when the Dual Down (Dual Down) when transmitting IPC data between the first and second SSL (30) 40 and the first and second TSL (50, 60) Only 4 bits of the total 8 bits of the channel are used and the remaining 4 bits are not used.

Therefore, the IPC alarm data received by the first and second message switches 10 and 20 is loaded into one of the remaining four bits and transmitted to the first and second TSLs 50 and 60.

In this case, the IPC alarm data transmitted from the first SSL 30 to the first and second TSL 50 and 60 through the aa1 and aa2 links is transmitted in a logic low state, and the SSL 40 The IPC alarm data transmitted to the first and second TSLs 50 and 60 through the bb1 and bb2 links are transmitted in a logic high state.

Accordingly, when the first and second TSLs 50 and 60 select four receiving links in consideration of the IPC alarm data transmitted from the first and second SSLs 30 and 40, when the four receiving links have no abnormality, The first and second TSLs 50 and 60 receive IPC data received on the aa1 and aa2 links in which the IPC alarm is in a logic low state.

In addition, when the state of the aa2 link transmitted by the first SSL 30 is bad, the first TSL 50 selects the IPC data received on the aa1 link, and the second TSL 60 receives the aa2 link state because the bad state. Select the IPC data received on the bb1 link.

In this case, the first and second TSLs 50 and 60 transmit the state of the reception link and the IPC alarm data received from the first and second SSLs 30 and 40 to the third and fourth message switches in the ASS 2. 70) (80).

Then, the IPC alarm data transmitted from the first TSL 50 to the third message switch 70 is transmitted to the logic low, and the IPC alarm data transmitted from the second TSL 60 to the fourth message switch 80 is logic. Transmitted high.

The third and fourth message switches 70 and 80 select the received IPC data in consideration of the IPC alarm data. The third message switch 70 selects the IPC data received from aaa1 and the fourth message switch 80. ) Selects the IPC data received from aaa2.

Thus, if the fourth message switch 80 is active and the aaa2 path is bad, the logic low is selected by the IPC alarm condition.

When the logic low is selected, the fourth message switch 80 is switched from the third message switch 70 to the normal communication of data on the IPC path.

1B is a system configuration diagram for performing a problem solving method on an IPC path when an ASS link is 4K according to the present invention, and includes INS 3 and ASS 4 and first, second, third and fourth message switches. 100, 110, 200, 210, 1, 2, 3, 4 SSL 120, 130, 140, 150, and 1, 2, 3, 4 TSL 160 ( It consists of 170, 180, 190.

The lower end link composed of the first and second SSL 120 and 130 in the INS 3 and the first and second TSL 160 and 170 in the ASS 4 is used as a master, and the INS (3) The upper end link composed of the third and fourth SSL 140 and 150 inside the third and fourth TSL 180 and 190 inside the ASS 4 is called a slave.

In addition, when the IPC path and the optical fiber link composed of the master are normal, the third and fourth message switches 200 and 210 may be activated to transmit IPC data from the master to the third and fourth message switches 200 and 210. Active) state.

At this time, if the slave maintains a standby state and an error such as communication failure on the IPC path occurs in the master, the slave may transmit IPC data to the third and fourth message switches 200 and 210. The message switch 200 or 210 enters an active state.

When the IPC path returns to normal from the master, the master becomes active and the slave becomes standby so that the problem in the IPC path when the ASS (4) link is 4K can be solved as a redundancy device.

As described above, the present invention described above provides a section in which normal IPC data is transmitted using the information on the IPC alarm in the IPC data receiving section by transmitting information on the sending IPC alarm to the receiving message switch in the IPC path. By selecting the IPC path, the IPC data can be transmitted and received normally.

Claims (1)

A device in an electronic switchboard for transmitting IPC data from a main processor as alarm data informing of a transmission path status, The first and second message switches and the first and second SSL are configured to be redundantly connected, and the first and second message switches apply IPC data and the IPC alarm data to the first and second SSL, respectively. The first and second SSL may include: an INS for selecting a transmission path from the first and second message switches based on the alarm data; And first and second TSLs redundantly connected to the first and second SSLs in the ASS, and third and fourth message switches redundantly connected to the first and second TSLs. An ASS for selecting a transmission path with the first and second SSLs according to IPC alarm data, and the third and fourth message switches selecting a transmission path with the first and second TSLs according to the alarm data; The third and fourth message switches and the first and second TSLs are redundantly connected, and the third and fourth message switches apply IPC data and the IPC alarm data to the first and second TSLs, respectively. The first and second TSLs include: an ASS for selecting a transmission path from the third and fourth message switches based on the alarm data; And first and second SSL switches redundantly connected to the first and second TSLs in the INS, and first and second message switches redundantly connected to the first and second SSLs. The transmission path with the first and second TSL is selected according to IPC alarm data, and the first and second message switches select an INS for selecting the transmission path with the first and second SSL according to the alarm data. Redundancy apparatus for solving the problem on the IPC path, characterized in that provided.