KR20010003433A - Protection switching method for ring type atm transmission system - Google Patents

Abstract

PURPOSE: A method for protection switching in a ring type asynchronous transfer mode(ATM) transmission device, is provided to implement an ATM system of a transmission device configured with a ring type network, thereby reducing loads and minimizing the delay of a switching time. CONSTITUTION: If one transmission device detects an error in an optical line connected thereto, an operating and maintenance(OAM) cell loading self identification information is transmitted in a direction equal to a cell transmitting direction of the optical line. Protection switching is performed, in order to receive an asynchronous transfer mode(ATM) cell from an optical line transmitting the ATM cell in a direction different from the transmitting direction of the optical line having an error. If one transmission device receives an OAM cell from another device, self identification information is loaded to the OAM cell and transmitted in a direction equal to a transmitting direction of the OAM cell. Protection switching is performed, to allow ATM cells from a device, wherein the received OAM cell is transmitted and identification information is not inserted in the received OAM cell, to receive OAM cells transmitted to a direction different from the transmitting direction of the OAM cell.

Description

PROTECTION SWITCHING METHOD FOR RING TYPE ATM TRANSMISSION SYSTEM}

The present invention relates to an asynchronous transfer mode (hereinafter referred to as ATM) ring structure transmission system, and more particularly to a method of protection switching.

In recent years, communication services have shifted from voice services such as telephones to data services such as the Internet, video telephony, and video on demand. In particular, the data communication method, which unconditionally allocates a certain communication frequency range like the existing ISDN or leased line, is difficult to absorb a small and intermittent data communication structure such as the Internet, and thus, the development of ATM communication equipment is required.

Accordingly, under the leadership of Korea Telecom, ATM communication equipment called FLC (Fiber Loop Carrier) -C was developed and the service is being tested. The FLC-C is largely composed of a mother country equipment and a plurality of home equipments, and the home equipment and a plurality of home equipments are composed of a star structure network, and have an optical line protection function.

The FLC-C has been improved to be composed of a ring structure network and a double star structure network to adapt to service areas and situations. However, the construction of domestic equipment in the form of ring-structured network has already been common in SDH communication equipment, but the ATM method does not have international standards and no products have been commercialized.

ATM ring transfer equipment for protection switching in FLC-C composed of such a ring network has not been commercialized yet. However, in the case of the proposed or proposed situation in the International Telecommunication Union (ITU), it is required to switch using ATM OAM signals for each of the VP / VC connections in a system existing in the ring network. This method increases the load for protection switching in a system with many connections. Therefore, in ITU, a group of VP / VCs are formed and organized into a connection group so that a representative ATM OAM signal of one group indicates a failure. Protection switching was performed for all connections in the group. However, this method was difficult to apply because of many ambiguities in the method as well as the standard, it can cause a lot of impact on the subscriber service in the transfer operation performed according to the transfer time by the ATM alert.

As described above, the protection switching method of the transmission apparatus of the ATM system configured with the conventional ring structure network has a problem that the load is large or the switching time is delayed.

Accordingly, an object of the present invention is to provide a protection switching method of a ring structure asynchronous transmission mode transmission equipment capable of minimizing the delay of the transfer time with less load in an ATM transmission equipment composed of a ring structure network.

1 is a block diagram of a FLC-C system according to a preferred embodiment of the present invention,

2 is a structural diagram of an APS cell according to a preferred embodiment of the present invention;

3 is a schematic structural diagram of a second slave device of FIG. 1;

4 is a process flow diagram of the controller of FIG. 3;

5 is a processing flowchart of the first FPGA of FIG. 3;

6 is a process flow diagram of the second FPGA of FIG.

7 is a schematic configuration diagram of the mother station apparatus of FIG. 1;

8 is a diagram illustrating a memory map of FIG. 7;

9 is a flowchart of a process of the CPU of FIG. 7;

FIG. 10 is a flowchart of processing of FPGAa of FIG. 7;

11 is a process flow diagram of the FPGAb of FIG.

The present invention provides a protection switching method for a ring structure asynchronous transmission mode transmission system in which a plurality of transmission devices for transmitting the same asynchronous transmission mode cell in both directions form a ring structure. When any one of the transmission apparatus detects an abnormality in the optical path connected to the transmission device, transmitting the maintenance cell carrying its identification information in the same direction as the cell transmission direction of the optical path, and in addition to the transmission of the maintenance cell Performing protection switching to receive the asynchronous transmission mode cell from the optical beam transmitting the asynchronous transmission mode cell in a direction different from the optical path detecting the abnormality; and wherein any one of the plurality of transmission devices maintains the other device. When the cell is received, its own identification information is put into the maintenance cell, and the transmission direction of the maintenance cell is the same. Transmitting the maintenance cell, and transmitting the maintenance cell to the asynchronous transmission mode cell from the plurality of transmission devices in which the identification information is not inserted into the received maintenance cell. And performing a protection switching to receive the transmission in a direction different from the direction.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. While many specific details are set forth in the following description and in the accompanying drawings, to provide a more general understanding of the invention, these specific details are illustrated for the purpose of illustrating the invention and are not meant to limit the invention thereto. And a detailed description of known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

A preferred embodiment of the present invention will be schematically described with reference to FIG. 1, which shows a schematic configuration diagram of a FLC-C system according to a preferred embodiment of the present invention. The mother station apparatus 100 and the first to fourth slave apparatuses 200 ₁ to 200 ₄ of the FLC-C system are configured in a ring-shaped network to perform communication in an ATM method. The FLC-C system may be provided with up to 16 local devices based on the number of nodes in the SDH ring. The mother station apparatus 100 and the first to fourth host apparatuses 200 ₁ to 200 ₄ simultaneously transmit in the first and second directions when transmitting ATM cells, and in the first and second directions when receiving ATM cells. Select and receive any one of the ATM cells transmitted to.

It will now be described to perform the protection transfer according to a preferred embodiment of the present invention. For example, if an abnormality occurs in the optical path A connecting the first slave device 200 ₁ and the second slave device 200 _{2 in} the path for transmitting the ATM cell in the first direction, the abnormality is determined. It is detected by the two-way station 200 ₂ . When the abnormality of the optical path A is sensed as described above, the second slave device 200 ₂ performs the protection switching to receive the ATM cell transmitted in the second direction.

When an abnormality occurs in the optical path A in the path for transmitting the ATM cell in the first direction, other devices also replace the ATM cell transmitted in the first direction through the optical path A in which the abnormality occurs. It should be able to receive ATM cell transmitted in the direction. To this end, the second host device 200 ₂ transmits the APS cell in which its identification information is inserted in the first direction. This APS cell indicates information on a path where no abnormality occurs. The transmission path of the ATM cell transmitted in the first direction from the device in which the identification information is inserted into the APS cell is normal, but the identification information is inserted into the maintenance cell. The transmission path of the ATM cell transmitted in the first direction from the non-device is indicative of an error.

The virtual path identifier (VPI) of the APS cell may use 0 * FF that is not used. In addition, the VCI (Virtual Channel Identifier) of the APS cell carries identification information on a device in a normal transmission path.

This will be described with reference to FIG. 2 which shows the structure of a header of the APS cell. The header is composed of Generic Flow Control (GFC), VPI, VCI, and Payload Type Identifier (PTI). 0 * FF is used as the VPI, and each bit of the VCI is used as an area for inserting identification information of a device in a normal transmission path. That is, the 16 bits of the VCI are configured as areas for carrying identification information about the mother station device and the first to the fifteenth slave device. In this case, when the broadcasting identifier is to be used, the number of local devices capable of storing the identification bit may be reduced by one.

When such an APS cell is transmitted in the first direction, the third local station apparatus 200 ₃ receives the APS cell and performs protection switching according to the information inserted in the APS cell. That is, since only the identification information of the second local station apparatus 200 ₂ is inserted into the APS cell, the third local station apparatus 200 ₃ transmits the second local station apparatus 200 ₂ among the ATM cells received in the first direction. Protection switching is performed to receive everything transmitted in the second direction. In addition to performing the protection switching as described above, the third slave device 200 ₃ further inserts its own identification information into the APS cell and transmits it in the first direction to inform the fourth slave device 200 _{4 of the} fact.

At this time, the fourth, the APS cell for receiving the local device (200 _4), the second, the third, so that the identification information for the local device (200 _2, 200 ₃₎ is inserted, the fourth station device (200 ₄₎ comprises a first direction The protection switching is performed to receive all of the ATM cells received by the second and third self-administration apparatuses 200 ₂ and 200 ₃ that are not transmitted in the second direction.

In this manner, the mother station apparatus 100 and the second to fourth host apparatuses 200 ₂ to 200 ₄ are transmitted in the second direction with respect to the ATM cell transmitted in the first direction through the optical path A in which an abnormality occurs. While protection switching to receive the transmission, the protection switching is not performed for the ATM cell transmitted in the first direction without passing through the optical path A.

As described above, according to the preferred embodiment of the present invention, when each of the mother station apparatus 100 and the first to fourth slave apparatuses 200 ₁ to 200 ₄ senses an abnormality of the optical path connected thereto, the ATM cell of the optical path In addition to protection switching to receive ATM cells transmitted in the opposite direction to the transmission direction, the APS cell in which its identification information is inserted is transmitted in the ATM cell transmission direction of the detected light beam.

In addition, when each of the mother station apparatus 100 and the first to fourth host apparatuses 200 ₁ to 200 ₄ receives an APS cell from one direction, the mother station apparatus 100 and its first to fourth station apparatuses 200 ₁ to 200 ₄ continuously transmit their own identification information to the APS cell. do. In addition, each of the mother station apparatus 100 and the first to fourth host apparatuses 200 ₁ to 200 ₄ does not perform protection switching on the ATM cell from the apparatus in which the identification information is inserted into the APS cell. For an ATM cell from a device in which no identification information is inserted in the APS cell, protection switching is performed so as to receive an ATM cell transmitted in a direction different from that of the APS cell.

Since the operations for protection switching performed in the first to fourth slave devices 200 ₁ to 200 ₄ are the same, the second slave device 200 ₂ will be described below in detail.

First, the second reference to a schematic configuration of a third block diagram showing a station unit (200 _2), the second station unit (200 ₂₎ comprises a 1ONIU (Optical Network Interface Unit) (202) and the 2ONIU (208 ) And an OMCU (ONU Main Control Unit) 214.

The first UNI 204 of the first ONIU 202 receives the optical signal transmitted in the first direction from the first optical path, extracts an ATM cell from the optical signal, and provides the first cell to the first Field Programmable Gate Array (FPGA) 206. do. In addition, the first UNI 204 detects an abnormality of the optical path from the state of the optical signal from the first optical path and provides the corresponding information to the first FPGA 206. In addition, the first UNI 204 converts an ATM cell provided by the first FPGA 206 into an optical signal and transmits the optical signal in a second direction through a second optical path. The first FPGA 206 provides the controller 216 of the OMCU 214 with information on the optical path abnormality detected by the first UNI 204 and generates an APS cell in which its identification information is inserted, thereby generating a second ONIU. Through 208 to the third optical path. Also, the first FPGA 206 provides or discards an ATM cell provided by the first UNI 204 to an ATM cell bus (not shown) according to a protection transfer command of the controller 216 of the OMCU 214. When the second ONIU 208 provides the APS cell, the first FPGA 206 transmits the first FPGA 204 to the second optical path through the first UNI 204. In addition, when the first UNIG 204 provides the APS cell, the first FPGA 206 copies the APS cell, provides one to the controller 216 of the OMCU 214, and inserts additional identification information into the other. After the transmission to the third optical path through the second ONIU (208).

The second UNII 210 of the second ONIU 208 receives the optical signal transmitted in the second direction from the fourth optical path and extracts an ATM cell from the optical signal to provide it to the second FPGA 212. In addition, the second UNI 210 detects an abnormality of the fourth optical line from the state of the optical signal from the fourth optical line and provides the corresponding information to the second FPGA 212. In addition, the second UNI 210 converts an ATM cell provided by the second FPGA 212 into an optical signal and transmits the optical signal in a first direction through a third optical line. The second FPGA 212 provides the controller 216 of the OMCU 214 with information on the optical path abnormality detected by the second UNII 210, generates an APS cell, and generates a second APS cell through the first ONIU 202. Transmit by light. In addition, the second FPGA 212 provides or discards an ATM cell provided by the second UNII 210 to the ATM cell bus according to a protection transfer command of the controller 216 of the OMCU 214. When the first ONIU 202 provides an APS cell, the second FPGA 210 transmits the second FPGA 210 to the third optical path through the second UNII 210. In addition, when the second FPGA 212 provides the APS cell, the second FPGA 212 copies the APS cell, provides one to the controller 216 of the OMCU 214, and further inserts its own identification information into the other. After the transmission to the second optical path through the first ONIU (202).

The controller 216 of the OMCU 214 controls the first and second ONIUs 202 and 208 as a whole and performs protection switching according to the APS cells provided from the first and second ONIUs 202 and 208.

The operation of the controller 216 of the second transmission device 200 ₂ and the first to second FPGAs 206 and 212 will now be described with reference to the processing flowcharts of FIGS. 4 to 6.

First, referring to FIG. 4, which illustrates a process flow of the controller 216 of the OMCU 214, in step 300, the controller 216 detects an abnormality of the first optical path by the first UNI 204. Search if 1FPGA 206 notifies. In this case, when the controller 216 is notified of the abnormality of the first optical line, the controller 216 proceeds to step 302 and performs protection switching to receive ATM cells transmitted through the fourth optical line for all ATM cells. If an abnormality in the first optical path is not detected in step 300 or if the protection transfer in step 302 is completed, the controller 216 proceeds to step 304. In step 304, the controller 216 detects an abnormality of the fourth optical path by the second UNI 210 and searches whether the second FPGA 210 notifies it. In this case, when the controller 216 is notified of the abnormality of the fourth optical line, the controller 216 proceeds to step 306 and performs protection switching to receive the ATM cells transmitted through the first optical fiber for all ATM cells. If the abnormality of the fourth optical path is not detected in step 304 or the protection transfer in step 306 is completed, the controller 216 proceeds to step 308. In step 308, the controller 216 searches whether the first FPGA 206 provides the APS cell received through the first optical path. At this time, if the first FPGA 206 provides the APS cell, the controller 216 proceeds to step 310, otherwise proceeds to step 312. In step 310, the controller 216 receives a device from which the identification information is not inserted in the received APS cell without performing protection switching on the ATM cell from the device in which the identification information is inserted in the received APS cell. Protection switching is performed to receive ATM cells from the fourth optical path. If the first FPGA 206 does not provide the APS cell in step 308 or the protection transfer of step 310 is completed, the controller 216 proceeds to step 312 and receives the APS cell received through the fourth optical path. Search whether the second FPGA 212 provides. At this time, if the second FPGA 212 provides the APS cell, the controller 216 proceeds to step 316, otherwise proceeds to step 314 to perform the corresponding operation. In step 316, the controller 216 does not perform the protection switching on the ATM cell from the device in which the identification information is inserted into the received APS cell, but from the device in which the identification information is not inserted in the received APS cell. The protection switching is performed to receive the ATM cell of the first optical path.

The operation of the first FPGA 206 will now be described with reference to FIG. 5, which shows a processing flowchart of the first FPGA 206. In operation 400, the first FPGA 206 detects whether the first UNII 204 detects an abnormality of the first optical path and provides the corresponding information. At this time, if the first FPGA 206 provides the information according to the abnormal detection of the first optical path, the first FPGA 206 proceeds to step 402 to notify the controller 216 of the OMCU 214 of the abnormal optical path detection. do. After the notification of abnormality detection of the first optical path as described above, the first FPGA 206 proceeds to step 404 to generate an APS cell in which its identification information is inserted and transmits it to the third optical path through the second ONIU 208. If no abnormality is detected in the first optical path in step 400 or if the APS cell is transmitted in step 404, the first FPGA 206 proceeds to step 406. In step 406, the first FPGA 206 searches whether the second ONIU 208 provides an ASP cell. In this case, the first FPGA 206 proceeds to step 408 if the second ONIU 208 provides the APS cell, and proceeds to step 410. In step 408, the first FPGA 206 transmits the APS cell provided from the second ONIU 208 to the second optical path through the first UNI 204, and then proceeds to step 410. In step 410, the first FPGA 206 searches whether the first UNI 204 provides the APS cell received from the first optical path. At this time, the first FPGA 206 proceeds to step 414 when the first UNI 204 receives the APS cell from the first optical path, and otherwise proceeds to step 412 to perform the operation. In step 414, the first FPGA 206 generates two APS cells by copying the received APS cells, and then proceeds to step 416. In step 416, the first FPGA 206 inserts the identification information indicating the second slave device 200 ₂ into one of the two APS cells and transmits the identification information to the third optical path through the second ONIU 208. Thereafter, the first FPGA 206 proceeds to step 418 to provide the other of the two APS cells to the controller 216.

The operation of the second FPGA 212 will now be described with reference to FIG. 6, which shows a processing flowchart of the second FPGA 212. In operation 500, the second FPGA 212 detects whether the second UNII 210 detects an abnormality of the fourth optical path and provides corresponding information. In this case, when the second UNII 210 provides the information according to the abnormal detection of the fourth optical line, the second FPGA 212 proceeds to step 502 and notifies the controller 216 of the OMCU 214 of the abnormal detection of the fourth optical line. do. Thereafter, the second FPGA 212 proceeds to step 504 to generate an APS cell in which its identification information is inserted, and transmits the APS cell to the second optical path through the first ONIU 202. If no abnormality is detected in the fourth optical path in step 500, or after transmitting the APS cell in step 504, the second FPGA 212 proceeds to step 506 in which the first ONIU 202 selects the APS cell. Search for it. In this case, the second FPGA 212 proceeds to step 508 when the first FPGA 202 provides the APS cell, and otherwise proceeds to step 510. In operation 508, the second FPGA 212 transmits the APS cell provided from the first ONIU 202 to the third optical path through the second UNI 210. In operation 510, the second FPGA 212 searches whether the second UNII 210 receives and provides an APS cell from the fourth optical path. In this case, the second FPGA 212 proceeds to step 514 when the second UNI 210 receives and provides the APS cell from the fourth optical path, and otherwise proceeds to step 512 to perform the corresponding operation. In step 514, the second FPGA 212 generates two APS cells by copying the received APS cells, and then proceeds to step 516. In step 516, the second FPGA 212 inserts its identification information into one of the two APS cells and transmits the identification information to the second optical path through the first ONIU 202. Thereafter, the second FPGA 212 proceeds to step 518 and provides the other of the two APS cells to the controller 216.

Now, an operation for protection switching performed in the mother station apparatus 100 will be described. First, when showing a schematic configuration of a parent station apparatus 100 with reference to FIG. 7, the parent station apparatus 100 is provided with a plurality of OLIU (102 ₁ ~102 _N). Since the ring formed by the slave devices is connected to the OLIU, a plurality of rings including the slave devices may be connected to the mother station apparatus 100. In particular, the OLIU 102 ₁ is connected to a ring consisting of first to fourth trace devices in accordance with a preferred embodiment of the present invention. The ASICa 104 of the OLIU 102 ₁ receives the optical signal transmitted in the first direction from the A optical path, extracts an ATM cell from the optical signal, and provides it to the FPGAa 106. In addition, the ASICa 104 detects an abnormality of the optical path from the state of the optical signal from the A optical path and provides the corresponding information to the FPGAa 106. In addition, the ASICa 104 converts an ATM cell provided by the FPGAa 106 into an optical signal and transmits the optical signal in the second direction through the B optical path. The FPGAa 106 provides the CPU 116 of the HDT Main Control Unit (HMCU) 112 with information about an optical path error detected by the ASICa 104. In addition, the FPGAa 106 provides or discards an ATM cell provided by the ASICa 104 to an ATM cell bus (not shown) according to a protection transfer instruction of the CPU 116 of the HMCU 112. The FPGAa 106 stores the APS cell when the ASICa 104 provides the APS cell and deletes the APS cell when the CPU 112 reads it. The ASICb 108 of the OLIU 102 ₁ receives the optical signal transmitted in the second direction from the D optical line and extracts an ATM cell from the optical signal to provide it to the FPGAb 110. In addition, the ASICb 108 detects an abnormality of the optical path from the state of the optical signal from the D optical path and provides the corresponding information to the FPGAb 110. In addition, the ASICb 108 converts the ATM cell provided by the FPGAb 110 into an optical signal and transmits the optical signal in the first direction through the C optical path. The FPGAb 110 provides the CPU 116 of the HMCU 112 with information about an optical path abnormal detected by the ASICb 108. In addition, the FPGAb 110 provides or discards an ATM cell provided by the ASICb 108 to an ATM cell bus according to a protection transfer instruction of the CPU 116 of the HMCU 112. The FPGAb 110 stores the APS cell when the ASICb 108 provides the APS cell, and then deletes the APS cell when the CPU 112 reads it.

The CPU 116 of the HMCU 112 performs protection switching using information on the optical path states provided by the FPGAa and b 106 and 110 or the APS cells stored in the FPGAa and b 106 and 110. In particular, as shown in FIG. 8, the memory unit 114 stores information about the own station apparatus for each of the rings connected to the mother station apparatus 100. Accordingly, the CPU 116 reads an APS cell and does not perform protection switching on the ATM cell from the local station in which the identification information is inserted in the APS cell, and other information is stored in the memory unit 114. Although the APS cell does not have identification information inserted in the APS cell, protection switching is performed for the ATM cell from the local station.

The operation of the CPU 116 and the operations of the FPGAa and b 106 and 110 will be described with reference to FIGS. 9 through 11.

First, referring to FIG. 9, which shows a process flow diagram of the CPU 116, the CPU 116 searches whether the FPGAa 106 notifies that an abnormality is detected in the A-ray path in step 500. At this time, the CPU 116 proceeds to step 602 when the FPGAa 106 notifies that the abnormal condition is detected on the A-ray path, and otherwise proceeds to step 604. In step 602, the CPU 116 performs protection switching to receive ATM cells from the D optical line for all ATM cells, and then proceeds to step 604. FIG. In step 604, the CPU 116 searches whether the FPGAb 110 notifies that an abnormality is detected in the D optical path. At this time, the CPU 116 proceeds to step 606 when the FPGAb 110 notifies that an abnormality is detected in the D optical path, and otherwise proceeds to step 608. In step 606, the CPU 116 performs protection switching to receive ATM cells from the A-ray paths for all ATM cells, and then proceeds to step 608. In step 608, the CPU 116 searches whether the APS cell is stored in the FPGAa 106. At this time, if the APS cell is stored in the FPGAa 106, the CPU 116 proceeds to step 610 to read the APS cell from the FPGAa 106 and for the ATM cell from the device in which the identification information is inserted into the APS cell. Without performing protection switching, protection switching is performed for an ATM cell from a device in which identification information is not inserted in the APS cell. Thereafter, the CPU 116 proceeds to step 612 to search whether the APS cell is stored in the FPGAb 110. At this time, if the APS cell is stored in the FPGAa 110, the CPU 116 proceeds to step 616, otherwise proceeds to step 614 to perform the corresponding operation. In step 616, the CPU 116 reads the APS cell from the FPGAb 110 and does not perform protection switching on the ATM cell from the device in which the identification information is inserted in the APS cell, and identifies the APS cell. Protection switching is performed for ATM cells from devices with no information inserted.

In addition, referring to FIG. 10, which illustrates a flow chart of the FPGAa 106, in step 700, the FPGAa 106 detects whether an ASICa 104 detects an abnormality of an A-ray and provides information accordingly. At this time, FPGAa 106 proceeds to step 702 when the ASICa 104 detects an abnormality of the A-ray path and provides the corresponding information. Otherwise, the FPGAa 106 proceeds to step 704. In step 702, the FPGAa 106 notifies the CPU 116 of abnormal detection of the A-rays. The FPGAa 106 then proceeds to step 704 to search whether the APS cell is received from the A-ray. At this time, the FPGAa 106 proceeds to step 708 when the APS cell is received from the A optical path, and otherwise proceeds to step 706 to perform the corresponding operation. In step 708, the FPGAa 106 stores the received APS cell. In this way, the stored APS cell is read by the CPU 116, and the APS cell read by the CPU 116 is deleted.

Referring to FIG. 11, which illustrates a flow chart of the FPGAb 110, in step 800, the FPGAb 110 detects whether the ASICb 108 detects an abnormality of the D-ray and provides information accordingly. In this case, the FPGAb 110 detects an abnormality of the D-ray and provides information according to the ASICb 108, and otherwise proceeds to step 804. In step 802, the FPGAb 110 notifies the CPU 116 of abnormality detection of the D optical path. The FPGAb 110 then proceeds to step 804 and searches whether the APS cell is received from the D optical line. At this time, the FPGAb 106 proceeds to step 808 when the APS cell is received from the D optical path, and otherwise proceeds to step 806 to perform a corresponding operation. In step 808, the FPGAb 110 stores the received APS cell. In this way, the stored APS cell is read by the CPU 116, and the APS cell read by the CPU 116 is deleted.

As described above, the present invention does not perform protection switching by monitoring the OAM cells for each ATM connection, and performs protection switching only by referring to information inserted in the APS cell, thereby reducing the load for protection switching.

In addition, since the APS cell is copied from the ONIU and transmitted to the next device, the devices belonging to the transmission system can perform protection switching at the same time with almost no changeover delay.

As described above, according to the present invention, it is possible to solve the problem of delayed transfer time, which may occur during protection switching of the ring structure ATM transmission system, and to reduce the load for switching.

Claims (2)

In the protection switching method of a ring structure asynchronous transmission mode transmission system in which a plurality of transmission devices for transmitting the same asynchronous transmission mode cell in both directions forms a ring structure, If any one of the plurality of transmission devices detects an abnormality in the optical path connected thereto, transmitting a maintenance cell carrying its identification information in the same direction as the cell transmission direction of the optical path; Performing protection switching to transmit the maintenance cell and to receive the asynchronous transmission mode cell from the optical path transmitting the asynchronous transmission mode cell in a direction different from the optical path detecting the abnormality; If any one of the plurality of transmission devices receives the maintenance cell from the other device, and transmitting the identification information to the maintenance cell in the same direction as the transmission direction of the maintenance cell, In addition to the transmission of the received maintenance cell, an asynchronous transmission mode cell from an apparatus in which no identification information is inserted into the received maintenance cell among the plurality of transmission devices is transmitted in a direction different from that of the maintenance cell. A protection switching method of a ring structure asynchronous transmission mode transmission system, characterized in that it comprises the step of performing a protection switching to receive. A plurality of transmission devices for transmitting the same asynchronous transmission mode cell in both directions are connected in the form of a ring, wherein one of the plurality of transmission devices is a mother station device, and the others are local devices. In the protection switching method, Transmitting a self-protection switching cell incorporating its own identification information in the same transmission direction as the transmission direction of the optical beam, when any one of the local apparatuses detects an abnormality in the optical path connected thereto; Performing protection switching to transmit the automatic protection switching cell and to receive an asynchronous transmission mode cell from an optical path in a transmission direction different from the transmission direction of the optical path detecting the abnormality; If any one of the transmitting apparatuses receives the auto-protection switching cell, inserting its identification information into the auto-protection switching cell and transmitting it in the same transmission direction as that of the auto-protection switching cell; For the asynchronous transmission mode cell transmitted from the self-protection switching cell and from which the identification information is not inserted into the received auto-protection switching cell among the self-protection switching cells, the transmission direction of the auto-protection switching cell is different from the transmission direction. Performing protection switching to receive the transmission in the transmission direction; Performing protection switching to receive an asynchronous transmission mode cell from an optical path of a transmission direction different from the transmission direction of the optical path detecting the abnormality, when the mother apparatus detects an abnormality in the optical path connected thereto; When the mother station apparatus receives the auto-protection switching cell, the transmission direction of the auto-protection switching cell for the asynchronous transmission mode cell from the own station apparatus in which the identification information is not inserted in the received auto-protection switching cell among the self-supporting cells. And performing protection switching to receive what is transmitted in a different transmission direction than that of the ring structure asynchronous transmission mode transmission system.