KR100212191B1 - Double system of optical data link in full electronic switching system - Google Patents

Abstract

The present invention relates to reliable redundancy of optical data links in all-electronic exchanges, and more particularly, to a redundancy system of optical data links in all-electronic exchanges to add cross hardware with minimal hardware functionality.

In the related art, since the point-to-point link configuration is used due to the difficulty in the installation and the price of the optical data link, there is a high possibility that an abnormal state of the service may occur, thereby having low reliability.

According to the present invention, with minimal hardware function, OPT transmits data to LNK of A side and B side using a divider, and LNK uses cross selector to select one data received from OPT of A side and B side using a selector. The implementation improves the reliability of the redundancy system of optical data link in all-electronic exchange.

Description

Redundancy System of Optical Data Link in Electronic Switching System

The present invention relates to reliable redundancy of optical data links in all-electronic exchanges. More particularly, the present invention relates to a redundancy system of optical data links in all-electronic exchanges with the addition of minimal hardware functions.

In the prior art, the system of the all-electronic exchanger is composed of three sub-systems as basic elements, as shown in FIG. 1, and a plurality of systems are installed in various forms according to the purpose of use. ASS (Access Switching Subsystem) (11) and one installed in the system and the interconnection network subsystem (INS) (12) that interconnects the ASS (11) and functions to be responsible for service and maintenance of the system. It includes a Common Control Subsystem (CCS) 13.

There are two types of data between the ASS 11 and the INS 12, one of which is 64 payloads of payload information and 64 Kbps of subscriber information, the other 64 (Kbps). IPC (Inter Processor Communication) data existing in the system to maintain the data of the system. The two kinds of data are multiplexed in the ASS 11 or INS 12 to be converted into serial data and transmitted to the INS 12 or ASS 11 through an optical data link.

However, in order to perform a more reliable transmission, it is composed of redundancy. Each of the subsystems 11, 12 and 13 is divided into A side 11A, 12A and 13A and B side 11B, 12B and 13B for simultaneous transmission. do. And the A side (11A, 12A, 13A) is configured by connecting the A side (11A, 12A, 13A) point-to-point between the B side (11B, 12B,) due to the difficulty of the price and installation of the optical data link 13B) B side 11B, 12B, 13B is comprised by the point-to-point connection. That is, for example, the A side ASS 11A is connected to the A side INS 12A and the B side ASS 11B is connected to the B side INS 12B.

On the other hand, as shown in FIG. 2, the optical data link duplication system includes a TSW (Time Switch) 14 for time slot converting data as a time switch (64 Kbps), and an IPC Unit (IPC Unit) for processing IPC data. And the optical data link together with the other side link to play the role of multiplexing and demultiplexing of data, matching 64 (Kbps) data for the TSW 14 and IPC data for the IPCU 15. The LNK (Link) 16 which matches the serial link with respect to the partner link, and the SSW (Space Switch) 17 which switches 64 (Kbps) data between the ASS 11 as a space switch, and the backplane. The board mounted on the rear side includes an OPT (Optic Board) 18 for converting an optical signal into an electrical signal and converting the electrical signal into an optical signal.

And TSW 14A, 14B, LNK 16A, 16B, SSW 17A, 17B, LNK 16A, 16B, IPCU 15A, 15B, and LNK 16A, 16B, as shown in FIG. ) Are each composed of cross redundancy, and the LNKs 16A1 and 16B1 and LNKs 16A2 and 16B2 are each composed of point-to-point. In other words, the TSW 14A, 14B, LNK 16A, 16B, SSW 17A, 17B, LNK 16A, 16B, IPCU 15A, 15B, and LNK 16A, 16B are matched with each other. If only one other axis is normal, the service is normally maintained. However, in the matching between the LNKs 16A1 and 16B1 and the LNKs 16A2 and 16B2, the same side must be normally maintained at the same time for service.

However, if the other side is normal in the matching between the LNK (16A1, 16B1) and LNK (16A2, 16B2) is not maintained, this time should be normal if cross-redundancy is implemented as shown in Table 1 below In case 3 and 3 consist of point-to-point, it is abnormal.

As described above, since the point-to-point link configuration is conventionally used due to the difficulty in the price and installation of the optical data link, there is a high possibility that an abnormal state of the service may occur, thereby having low reliability.

To solve the above problems; An object of the present invention is to provide a redundancy system of optical data links in an all-electronic exchange to improve the reliability of the system by adding a minimum hardware function to the redundancy system of the optical data links in the all-electronic exchange. do.

According to the present invention for achieving the above object, the A and B side LNK to match the TSW and IPCU, multiplex the data applied from the TSW and IPCU, and demultiplex the electrical signals applied to the TSW and IPCU Wow; It is mounted on the back side of the backplane and converts the optical signal applied from the partner link into an electrical signal and applies it to the A side and B side LNK, and the multiplexed electrical signal applied from the A side and B side LNK as an optical signal. In the redundancy system of the optical data link in the electron exchanger having the A-side and B-side OPT which is converted and applied to the counter side link, the A-side and the B-side OPT are respectively provided in the A-side and the B-side OPT. An A-side and a B-side splitter for distributing the electrical signal converted from the optical signal and applying it to the A-side and B-side LNK, respectively; The A side and B side LNK, respectively, characterized in that it comprises the A side and B side selector for selecting one of the error-free signal among the distributed electrical signals applied from the A side and B side distributor.

1 is a block diagram showing a system of a conventional all-electro-exchange device.

FIG. 2 is a block diagram showing the redundant system of optical data link in FIG.

Figure 3 is a block diagram showing a redundancy system of the optical data link in the electron exchanger according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

11: ASS (Access Switching Subsystem)

12: INS (Interconnection Network Subsystem)

13: Common Control Subsystem (CCS)

14: TSW (Time Switch) 15: IPCU (IPC Unit)

16, 20: LNK (Link) 17: SSW (Space Switch)

18, 30: OPT (Optic Board) 21: selector

31: Splitter 40: Backplane

Before explaining the configuration of the optical data link redundancy system in the electronic switching system according to an embodiment of the present invention, the first thing to keep in mind, first, because of the difficulty of the cost and installation of the optical data link using the optical fiber directly Secondly, it does not consist of cross redundancy, and secondly, minimum hardware is added to implement cross redundancy. That is, as shown in FIG. 3, in the redundancy system of the optical data link in the all-electron exchanger according to the embodiment of the present invention, the A side and the B side LNK 20A and 20B are respectively provided in the conventional redundancy system. And A side and B side distributors 31A, 31B provided in the B side selectors 21A, 21B and the A side and B side OPTs 30A, 30B, respectively.

The A-side and B-side selectors 21A and 21B select one error-free signal among the distributed electrical signals applied from the A-side and B-side dividers 31A and 31B, so that the A-side LNK 20A or B side is selected. Allow LNK 20B to demultiplex the distributed electrical signals.

The A side and B side distributors 31A and 31B distribute electrical signals obtained by converting optical data applied through an optical data link from the A side and B side OPTs 30A and 30B to the A side and B side. It applies to LNK20A, 20B, respectively.

The redundancy system of the optical data link in the electron exchanger according to the embodiment of the present invention operates as follows.

First, the service is maintained as shown in Table 2 below even when the other sides are normal in matching between the first LNKs 20A1 and 20B1 of the ASS and the second LNKs 20A2 and 20B2 of the INS.

First, when an error occurs in the B side 1LNK 20B1 and the A side 2LNK 20A2 in this case, the path of the optical data link for maintaining the service in the normal state will be described. The LNK 20B1 does not perform an operation because an error has occurred, and the A-side first LNK 20A1 matches TSW with 64 (Kbps) data or IPCU and IPC data and matches the data with the A-side 10PT (30A1). The 10th PT 30A1 of the A side converts the data into optical data and applies the same to the 20th PT 30A2 of the A side through an optical data link.

Accordingly, the A side 20PT 30A2 converts the optical data applied through the optical data link into an electrical signal, and the distributor 31A2 of the A side 20PT 30A2 distributes the corresponding electrical signal to the A signal. It is applied to the 2nd LNK 20A2 and B side 2LNK20B2, respectively.

Accordingly, since an error occurs in the A-side 2LNK 20A2, the selector 21A2 does not perform an operation and the selector 21B2 of the B-side 2LNK 20B2 receives the divided electrical signal. B-side 2LNK 20B2 is demultiplexed and applied to SSW or IPCU.

In contrast, the B side 2LNK 20B2 matches SSW and 64 (Kbps) data or IPCU and IPC data and applies the corresponding data to the B side 20PT 30B2, and the B side 20PT ( 30B2) converts the data into optical data and applies it to the B-side 10PT 30B1 through the optical data link.

Accordingly, the B-side 10PT (30B1) converts the optical data applied through the optical data link into an electrical signal, and the divider 31B1 of the B-side 10PT (30B1) distributes the corresponding electrical signal to the A. To the first LNK20A1 on the side and the first LNK 20B1 on the B side. Accordingly, the selector 21A1 of the A-side first LNK 20A1 receives the distributed electrical signal, and the A-side 1LNK 20A1 demultiplexes and applies the TSW or IPCU.

Meanwhile, referring to the path of the optical data link for maintaining service in the case where an error occurs in the first ANK 20L1 and the second BNK 20B2 of the third case, the A-side LNK ( 20A1), since an error has occurred, the B-side first LNK 20B1 matches TSW and 64 (Kbps) data or IPCU and IPC data and matches the data to the B-side 10PT (30B1). The B side tenth PT 30B1 converts the data into optical data and applies the optical data to the B side 20PT 30B2 through the optical data link.

Accordingly, the B side 20PT 30B2 converts optical data applied through the optical data link into an electrical signal, and the distributor 31B2 of the B side 20PT 30B2 distributes the corresponding electrical signal to the A side. 2LNK 20A2 and B side 2LNK 20B2, respectively.

Accordingly, since an error occurs in the B side 2LNK 20B2, the selector 21B2 does not perform an operation and the selector 21A2 of the A side 2LNK 20A2 receives the distributed electrical signal. The second side LNK 20A2 is demultiplexed and applied to the SSW or IPCU. On the contrary, the A side 2LNK 20A2 matches SSW and 64 (Kbps) data or IPCU and IPC data and applies the corresponding data to the A side 20PT 30A2, and the A side 20PT ( 30A2) converts the data into optical data and applies the same to the A-side 10PT (30A1) through the optical data link.

Accordingly, the A side 10PT 30A1 converts the optical data applied through the optical data link into an electrical signal, and the distributor 31A1 of the A side 10PT 30A1 distributes the corresponding electrical signal to the A signal. To the first LNK 20A1 and the B first LNK 20B1.

Accordingly, the selector 21B1 of the B side 1LNK 20B1 receives the distributed electrical signal, and the B side 1LNK 20B1 demultiplexes and applies the TSW or the IPCU. As described above, when transmitting and receiving data using the optical data link in the all-electronic exchange, the simple hardware dividers 31A1, 31B1, 31A2, and 31B2 are constructed by point-to-point due to the difficulty of the cost and installation of the optical data link. And selectors 21A1, 21B1, 21A2, and 21B2 were used to obtain the same effect as the configuration of cross-duplexing the optical fiber.

As described above, according to the present invention, the OPT transmits data to the LNK of the A side and the B side using the distributor, and the LNK selects one data received from the OPT of the A side and the B side using the selector. Since cross redundancy is implemented, the reliability of the redundancy system of optical data link in all-electronic exchange is improved.

Claims (1)

A side and B side LNKs 20A and 20B that match a TSW and an IPCU, multiplex the data applied from the TSW and the IPCU, and demultiplex an electrical signal applied to the TSW and the IPCU; It is mounted on the back side of the backplane 40, converts the optical signal applied from the partner side link into an electrical signal and applies it to the A side and B side LNKs 20A and 20B, and the A side and B side LNK 20A. A redundancy system of an optical data link in an all-electronic exchanger having A side and B side OPTs (30A, 30B) for converting a multiplexed electrical signal applied from a 20B) into an optical signal and applying the same to the counter link. The A side and B side OPTs 30A and 30B are respectively provided, and the A side and B side OPTs 30A and 30B distribute electrical signals converted from optical signals to the A side and B side LNKs 20A and 20B. And A side and B side distributors 31A and 31B respectively applied to The A and B side LNKs 20A and 20B, respectively; An A / B selector (21A, 21B) for selecting an error free signal among the distributed electrical signals applied from the A and B side dividers (31A, 31B). Redundancy system of optical data link.