KR100757900B1 - Method for managing vcg using lcas in eos transport device - Google Patents

Abstract

A VCG(Virtual Concatenation Group) management method in an EoS(Ethernet over SDH(Synchronous Digital Hierarchy)) transmission device is provided to manage a VCG in a software way, in order to allocate bandwidths effectively and dynamically in the EoS transmission device. A VCG management device receives VCG information set by an operator(S401,S402). The device defines the received VCG information as VCG data to generate the defined VCG data. The device sets the VCG data to a VCG channel on an SONET(Synchronous Optical Network)/SDH interface. The device manages the corresponding VCG channel by generating, modifying, and deleting data on the set VCG channel according to the VCG information set by the operator(S403-S417).

Description

Method for managing VCG using LCAS in EOS Transport Device}

1 is a diagram illustrating a configuration for providing a VCG management service in an EOS transmission apparatus according to an embodiment of the present invention;

2 is an exemplary diagram for providing a VCG management service using LCAS in an EOS transmission apparatus according to another embodiment of the present invention;

3 is a structural diagram of VCG data configured in the VCG management apparatus of the EOS transmission apparatus according to the present invention,

4 is a flowchart illustrating a VCG management method performed in a VCG management apparatus using VCG data defined by software in an EOS transmission apparatus according to the present invention; and

5 is a flowchart illustrating a process of an LCAS control apparatus according to an embodiment of a decision to operate according to the LCAS technique according to the present invention.

Explanation of symbols on the main parts of the drawings

110: operating system and other devices 120: VCG management device

130: failure detection unit 140: internal communication system

150: SONET / SDH interface 160: signal input terminal

170: LCAS controller

The present invention relates to a method of managing a virtual concatenation group (VCG) in an EOS (Ethernet over SDH) transmission apparatus, and in particular, an EOS transmission apparatus for managing VCG settings in software to dynamically allocate bandwidth in an EOS transmission apparatus. VCG management method in the

Synchronous Optical Networks (SONET) are currently applied to many service providers or carrier level networks. The form of SONET used in Europe, Asia, America, etc. is known as Synchronous Digital Hierarchy (SDH), which is composed of hierarchical topology, and voice and data on Layer 1.5. It is based on Time-Division Multiplexer (TDM).

On the other hand, the EOS transmission device has a wide bandwidth and can perform fast data transfer. Since signal transmission in an EOS transmitter is an important factor in determining the quality of service of the device, it is important to ensure signal continuity. The EOS transmitter has a multi-layer structure of SONET / SDH layer, EOS adaptation layer and Ethernet layer, and manages maintenance signals in each layer for input / output signals.

In order to accommodate Ethernet in the current transmission network, based on EOS technology, the service for the physical speed (10/100/1000 Mbps) of the Ethernet interface can be accommodated in the SDH transmission to provide the same quality for all Ethernet traffic. It is processed to handle a large amount of signal in the network, so that it can provide a stable service by quickly recovering the network failure caused by not only the failure of the transmission device itself but also the break of the optical line and the failure caused by natural disaster. have.

The EOS transmitter collects the fault condition of the operation signal and the preliminary signal in the SONET / SDH signal matching interface that processes the sync signal, and recovers the fault by selecting a good signal from the two signals when a fault occurs in a specific signal. In addition, the Link Capacity Adjustment Scheme (LCAS) of the EOS transmitter has a function of automatically eliminating, returning to, and reoccurring a fault path generated in a virtual concatenation (VCAT) and increasing or decreasing link capacity without an error.

In recent years, attempts have been made to impose various functions on EOS transmission devices, and the devices have become increasingly complex due to the expansion of software and hardware functions. However, when imposing these functions on the conventional EOS transmission device, it is difficult to operate by reflecting various setting information in connection with the operating system and other devices, making it difficult to manage VCG successfully and incubating message processing in VCG management using LCAS technique. There is a disadvantage in that the dynamic bandwidth allocation and failover performance is reduced by increasing.

Therefore, in the technical field to which the present invention belongs, there is a need for a VCG management technology for efficiently allocating bandwidth to perform various functions in an EOS transmission apparatus.

The present invention has been proposed in order to solve the above-described problems, by setting the VCG information set by the operator in the VCG management device of the EOS transmission apparatus to the SONET / SDH interface channel and writing the channel information to the VCG data software The purpose of the present invention is to provide a VCG management method in an EOS transmission device that reduces the load of hardware processing on the VCG by managing it.

In addition, another object of the present invention is to provide a dynamic bandwidth setting of the VCG set in the operating system and other devices by sharing the VCG data with the VCG management device by placing the LCAS control device when the VCG management device provides services in the EOS transmission device The present invention provides a method of managing a VCG in an EOS transmission device that can be software-enabled and can efficiently allocate bandwidth using the VCG management device and VCG data in a LCAS controller when a VCG failure is detected.

The present invention for achieving the above object, the first step of receiving the VCG information set by the operator in the VCG management device; A second step of defining and receiving the received VCG information as VCG data; Setting the VCG data as a VCG channel in a SONET / SDH interface; And a fourth step of generating, modifying, and deleting data on the set VCG channel according to the VCG information set by the operator to manage the corresponding VCG.

In an embodiment of the present disclosure, the fourth step may include: determining whether to generate, modify, and delete the VCG channel data according to the VCG information set by the operator; And storing the created, modified, and deleted VCG channel data.

In one embodiment of the present invention, the VCG channel data is a field for identification of the VCG, a field indicating the timeslots of the VCG, a field indicating the failure of the timeslot, the failure of the timeslot A field indicating a state of a timeslot, a field indicating a state of the timeslot, a failure and the number of timeslots of the timeslot in the VCG, a field indicating the state of the VCG, a field indicating whether the LCAS is enabled or disabled, and A field indicating the payload type of the VCG, a field indicating whether the Payload FCS Indicator (PFI) header for checking the frame check sequence (FCS) of the VCG is enabled or disabled, and a field indicating the directionality of the VCG set by the operator. It is preferable to include a field indicating the VCG failure, and an Unused field provided for a function to be added later. .

In this case, the timeslots are provisioned timeslots indicating the number of timeslots of the first timeslots of the timeslots of the VCG and active timeslots indicating the number of lengths of later timeslots. Can be distinguished.

In an embodiment of the present disclosure, the generation of the VCG channel data of the fourth step may include: checking the directionality of the VCG set by the operator; Generating data for a VCG channel that drops and adds a VCG if the VCG's directionality is bidirectional; Generating data for a VCG channel dropping or adding a VCG according to a drop or add when the VCG is unidirectional; And storing the generated VCG channel data in the VCG management apparatus.

In an embodiment of the present disclosure, the modification of the VCG channel data in the fourth step may include: searching at the VCG management apparatus using an identifier and a direction of the VCG channel data to be modified according to the VCG information set by the operator; And modifying the VCG channel data if the VCG channel data to be corrected exists in the VCG management apparatus as a result of the search, and generating new VCG channel data if the VCG channel data does not exist.

The modification of the VCG channel data may include determining whether the VCG information set by the operator and each VCG state information of the modified VCG channel data has changed; Changing VCG state information of the VCG channel data to be modified if it is changed; Determining whether LCAS state information, payload type information, PFI information, and directional information of the VCG are respectively modified in the VCG channel data; Deleting the VCG channel set in the current hardware, and storing VCG channel data deletion information corresponding to the deleted VCG channel in the VCG management apparatus if it has been modified; Determining if LCAS is enabled if not modified; And if it is not enabled, deleting the VCG channel set in the current hardware, and storing VCG channel data deletion information corresponding to the deleted VCG channel in the VCG management apparatus.

According to an embodiment of the present disclosure, the deletion of the VCG channel data of the fourth step may include: searching by the VCG management apparatus using an identifier and directionality in the data of the VCG channel to be deleted according to the VCG information set by the operator; And checking directionality of the VCG set by the operator when VCG channel data to be deleted exists in the VCG management apparatus. Deleting data for a VCG channel dropping and adding a VCG if the VCG has a bidirectional direction; Deleting data for a VCG channel dropping or adding a VCG according to whether the VCG is unidirectional if the VCG is unidirectional; And storing the deleted VCG channel data information in the VCG management apparatus.

According to an embodiment of the present invention, when generating VCG channel data in the fourth step, if the LCAS is enabled by reading a field indicating the LCAS state of the generated VCG channel data, it corresponds to active timeslots. The method may further include allocating dynamic bandwidth to the timeslot.

In one embodiment of the present invention, the present invention includes the steps of detecting whether a failure occurs in the VCG channel of the SONET / SDH interface; And when a failure is detected in the VCG channel, correcting a timeslot according to the failure.

The method of claim 10, wherein the failure of the VCG channel, LFS (Lost frame sync), CHEC (core Hec error), FCS (Frame Check sum error), GRPID (Group id error), MFI (MFI unlock) It may be at least one selected from Sequence Number Mismatch (SEQM), not aligned before writing on path (NAW), message CRC error (MCRC), State Machine Fail (SMFL), and RXMST (Rx_MST).

In one embodiment of the present invention, the SONET / SDH interface is STS_48L, STS_12L, STS_192L, STM_64, STM_16, VC3, VC4, STS_1L, STS_1P, STS_3L, STS_3cP, STS_12cP, STS_48cP, STS_192_Pc, STM_0, 4Cc, STM_0, 4c It may be at least one selected from VC4_64c and STM_4.

In addition, the present invention for achieving the above object, the first step of receiving the VCG information set by the operator in the VCG management apparatus; A second step of defining and receiving the received VCG information as VCG data; Setting the VCG data as a VCG channel in a SONET / SDH interface; A fourth step of allocating a dynamic bandwidth to a timeslot corresponding to an active timeslot when LCAS of the set VCG channel is enabled; Determining whether the VCG channel data can be modified or set as a new VCG channel without deleting the VCG channel set in hardware when the VCG channel is modified; A sixth step of performing dynamic bandwidth allocation by transferring corresponding VCG channel data to an LCAS controller when there is a change in the active timeslot of the VCG channel; And a seventh step of determining the time slot to be deleted and the time slot to be added and dynamically modifying the bandwidth allocation by comparing the time slot to be allocated with the previous bandwidth allocated time slot for the dynamic bandwidth allocation set by the operator in the LCAS controller. .

In one embodiment of the present invention, the VCG channel data, the field for identification of the VCG, the field indicating the time slot (Timeslot) of the VCG, the field indicating the failure of the time slot, the failure of the time slot A field indicating a state of a timeslot, a field indicating a state of a timeslot, a failure and the number of timeslots of the timeslot in the VCG, a field indicating a state of the VCG, a field indicating whether the LCAS is enabled or disabled, A field indicating a payload type of the VCG, a field indicating whether a Payload FCS Indicator (PFI) header for checking a frame check sequence (FCS) of the VCG is enabled or disabled, and a directionality of the VCG set by an operator Field, the field indicating the VCG failure, and an unused field prepared for a function to be added later. .

In an embodiment of the present disclosure, the third step may be configured to set the VCG channel according to the identifier and the directionality of the corresponding VCG channel according to the generated VCG data. Directionality is divided into bidirectional and unidirectional, and generating data for a VCG channel that drops and adds in bidirectional; And generating data for a VCG channel dropping or adding a VCG according to drop or add, if the VCG has a unidirectional direction.

In one embodiment of the present invention, detecting whether a failure occurs in the VCG channel; Confirming whether the VCG channel has failed in the LCAS controller; And generating a fault in the VCG channel and correcting a timeslot according to the dynamic bandwidth allocation due to the fault.

In addition, the present invention for achieving the above object, the VCG management device for creating and managing the VCG information set by the operator as VCG data, the failure detection unit for detecting the failure of the VCG channel and LCAS technique by applying the VCG management In the VCG management method in an EOS transmission apparatus comprising an LCAS control unit that performs a software software VCG bandwidth allocation by sharing the VCG data with the device,

Determining whether the LCAS of the VCG channel is enabled or whether a failure is detected in the VCG channel; If the LCAS of the VCG channel is enabled, reading the channel data stored in the VCG management apparatus from the LCAS controller and initializing a register necessary for dynamic bandwidth allocation by the VCG channel data set by the operator; Determining whether a previous position (prePos) or a current position (curPos) of a timeslot to be processed for dynamic bandwidth allocation remains; If it remains, it is determined whether the value of the current position (prePos) time slot of the previous time slot and the current position (curPos) time slot of the current time slot (curTimeslot) is equal, and if it is the same, the previous position (prePos) and the current position (4) increasing the index number of (curPos) to the third step; If it is different in the fourth step, it is determined whether the previous position (prePos) is greater than or equal to the previous number (preNum), which is the number of timeslots of the current hardware VCG channel. In this case, the current position (curPos) th time slot of the current time slot (curTimeslot) is added to the active timeslots of the current hardware VCG channel, and the index number of the current position (curPos) is determined. A fifth step of increasing the number to proceed to the third step; In the fifth step, when the time slot is to be subtracted by determining whether the reduction of the dynamic bandwidth allocated to the current VCG is necessary, the time before the previous position (prePos) of the previous time slot (preTimeslot) previously allocated to the dynamic bandwidth is generated. A sixth step of deleting the slot and increasing the index number of the previous position (prePos) to proceed to the third step; And a seventh step of determining whether to continue driving the LCAS controller if the previous position (prePos) or the current position (curPos) of the timeslot to be processed for dynamic bandwidth allocation remains in the third step.

According to an embodiment of the present disclosure, if a failure is detected in the VCG channel in the first step, reading a failure detected by a failure detection unit and retrieving the VCG channel of the time slot where the failure occurs in the VCG management apparatus; Dynamically reducing the bandwidth of the retrieved VCG timeslots and modifying active timeslots of VCGs stored in the VCG management apparatus; And repeating the above steps until dynamic bandwidth allocation is performed for all failures generated by the failure detection unit.

Other objects, features and advantages of the present invention will become more apparent from the following detailed description of the embodiments with reference to the accompanying drawings. Hereinafter, a preferred embodiment of the VCG management method in the EOS transmission apparatus according to the present invention will be described with reference to the accompanying drawings.

1 is an exemplary diagram of a system configuration for providing a VCG management service in an EOS transmission apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a system for providing a VCG management service in an EOS transmission apparatus according to the present invention includes an operation system and other apparatus 110 for receiving VCG information set by an operator, and the operation system and other apparatuses. A VCG management device 120 which receives the VCG information from the 110 and creates and manages the VCG data; and a SONET / SDH interface 150 in which the VCG information is set as a channel using an internal communication system 140; If the VCG failure occurs while operating the VCG in hardware, it consists of a plurality of failure detection unit 130 detects the failure through the signal input terminal 160 and delivers it to the VCG management device (120).

In order to manage the VCG in the EOS transmission apparatus according to the present invention, the operator transmits the VCG information set in the operating system and the other device 110 to the VCG management apparatus 120, and the VCG management apparatus 120 to the operator. By setting the VCG information set by the channel of the SONET / SDH interface 150 and managing the channel information as the VCG channel data to enable efficient bandwidth use, if a failure occurs in the VCG to the operating system and other devices 110 Report this to detect failures. In this process, the VCG management device 120 defines and stores the VCG information set in the operating system and the other device 110 in the form of VCG data to manage the VCG in software, and generates the VCG channel data. The VCG is managed through modification and deletion.

In this case, the VCG failure detected by the failure detection unit 130 is preferably LFS (Lost Frame Sync), CHEC (Core Heck Error), FCS (Frame Check sum error), GRPID (Group id error), MFI (MFI unlock) ), Sequence Number Mismatch (SECM), Not Aligned Before Writing on Path (NAWP), Message CRC error (MCRC), LCAS State Machine fail (SMFL) and RXMST (Rx_MST).

2 is a diagram illustrating a configuration for providing a VCG management service using LCAS in an EOS transmission apparatus according to another embodiment of the present invention.

Referring to FIG. 2, a system for providing a VCG management service in an EOS transmission apparatus according to another embodiment of the present invention includes an operation system and other apparatus 110 for receiving VCG information set by an operator, and the operation system. And a SONET / SDH in which the VCG setting information is set as a channel by using the VCG management device 120 which receives the VCG information from the other device 110, writes the VCG data, and manages the same, and uses the internal communication system 140. If the VCG failure occurs while operating the interface 150 and the VCG in hardware, a plurality of failure detection units 130 and LCAS techniques are used to detect a failure through the signal input terminal 160 and transmit the failure to the VCG management device 120. By applying the VCG management device 120 and the VCG data is shared by the LCAS controller 170 for performing a dynamic VCG bandwidth allocation by the software software.

2 and 1, the same components perform the same operation. In particular, the VCG management device 120 sets the VCG information set by the operator to manage the VCG in software as a channel of the SONET / SDH interface (defined as VCG data format and stored as VCG data.), And the channel By managing the information as VCG channel data enables efficient bandwidth usage. As described above, the VCG management apparatus 120 defines and stores VCG information set in the operating system and the other apparatus 110 in VCG data format in order to manage VCG in software, and generates and modifies the VCG channel data. The VCG is managed through and deletion. In this case, the LCAS controller 170 enables the software to dynamically set the bandwidth of the VCG set in the operating system and the other device 110 by sharing the VCG data with the VCG management device 120. In addition, the LCAS controller 170 enables dynamic bandwidth allocation by the failure detection unit 130 using the VCG data in connection with the VCG management device 120 when a failure occurs in the VCG.

3 is a structural diagram of VCG data stored and used by software in the VCG management apparatus of the EOS transmission apparatus according to the present invention.

Referring to FIG. 3, the structure of the VGC data managed by the VCG management apparatus of the EOS transmission apparatus according to the present invention includes a VCG number field 301 for identifying a VCG, and a time of the identified VCG. A timeslot field 311 indicating a slot, a failure field (Failure (T)) 310 for determining a failure of the timeslot, and a state of the timeslot field 311 due to the failure of the timeslot S field 309 for determining whether the device is up or down, and timeslot length for determining the number of timeslot states and failures and the number of timeslots in the VCG. Field 302, an S field 303 which is a field for determining whether a state of the VCG divided by the identifier is up or down, and whether the corresponding VCG is a VCG for operating as an LCAS. To determine if LCAS is enabled or not L field 304 indicating whether or not (disable), a T field 305 for determining whether the payload type of the VCG is VC3 or VC4, and a function of checking a frame check sequence (FCS) of the VCG. P field 306 that determines whether the Payload FCS Indicator (PFI) header is enabled or disabled, addDrop, unidirectional in the case of bidirectional depending on whether the VCG is set to bidirectional or unidirectional. D field 307 for dividing into a drop and add, a failure field 308 for determining a failure occurring in the VCG, and a VCG failure 308 and a time slot ( It consists of an unused field 314 that fills a byte boundary in order to process the functions added afterwards 311 in software and to speed up reading of the VCG data.

In the structure of this VCG data, the timeslot 311 is a provisioned timeslots 312 indicating the number of timeslots 302 of the first timeslot 311 of the timeslot 311 that the VCG has. And Active Timeslots 313 indicating the number of later timeslot lengths 302.

4 is a flow diagram illustrating a VCG management method performed in a VCG management apparatus using VCG data defined by software in an EOS transmission apparatus according to the present invention.

Referring to FIG. 4, first, the VCG management apparatus 120 is started (S401), and the VCG information set by the operator is received from the operating system and the other apparatus 110, and the VCG data having the structure as shown in FIG. 3 is received. It creates (S402). In this case, the VCG data is VCG Number field 301, Timeslot Length field 302, S field 303, L field 304, T field 305, P field 306, D field 307, It is composed of Failure field 308, S field 309, Failure (T) field 310 and Timeslot field 311, the VCG management device 120 is divided by the identifier of the VCG Number according to the characteristics of each VCG Has all the VCGs created.

Upon reception of VCG information from the operating system and the other device 230 in step S402, it is determined whether the EOS transmission apparatus is initializing (S403), and if so, the SONET according to the VCG information set by the operator. Generate as VCG channel data of the / SDH interface (S404). Subsequently, the L field 304 of the VCG data is checked to determine whether the LCAS is enabled or disabled (S405). If the LCAS is enabled, a preliminary time slot written in the VCG data is provided. Among the time slots 311 included in Timeslots 312, VCG data is compensated for by setting the time slots influencing the initial bandwidth by the LCAS in the Active Timeslots 313 (S406). If disabled, no active timeslot 313 is set. In other words, if the LCAS is enabled, dynamic bandwidth is allocated to timeslots corresponding to active timeslots.

Subsequently, the setting direction of the VCG is checked from the D field 307 of the VCG data (S407), and if it is bidirectional (addDrop), data of the VCG channel capable of dropping and adding the VCG is generated and bidirectional to the hardware. If the channel is set as a channel (S408, S409), if the unidirectional is add, data of a channel to which the VCG can be added is generated (S410), and if the unidirectional is drop, data of a channel to which the VCG can be dropped is generated (S411). The VCG channel data generation information generated as described above is stored in the VCG management apparatus 120 (S412). In addition, it is determined whether to continue to drive the VCG management device 120 (S427), if not continue to drive if you continue to receive the VCG information set again from the operating system and the other device 230 Wait for (S402).

On the other hand, if not in the initialization of the EOS transmission unit in step S403 confirms the request for the operator's VCG from the VCG information received from the operating system and the other device 230 whether the generation of VCG channel data of the SONET / SDH interface, It checks whether it is a modification or deletion and branches according to generation, modification or deletion of the VCG channel data (S413). If the VCG channel data is generated in step S413, the processes of steps S404 to S412 are performed. If the VCG channel data is modified in step S413, the process proceeds to step S414. If the VCG channel data is deleted, the process proceeds to step S418.

First, if the VCG channel data is corrected in step S413, it is searched whether the corresponding VCG data to be modified exists in the VCG management apparatus 120 (S414). At this time, the search of the VCG data is to check whether there is VCG data stored in the VCG management device 120 by checking the VCG number field 301 and the D field 307 of the VCG data. It is determined whether the corresponding VCG data exists in the VCG management apparatus 120 (S415). If not, the process proceeds to step S404 to generate VCG channel data (S404 to S412). If the corresponding VCG data exists in the VCG management apparatus 120, VCG channel data is modified (S416). Subsequently, the VCG channel data modification information is stored in the VCG management apparatus 120 (S417). In addition, it is determined whether to continue to drive the VCG management device 120 (S427), if not to continue to continue and continue to drive to receive the VCG information set again from the operating system and the other device 230 Wait (S402).

Next, if the VCG channel data is deleted in step S413, it is searched whether the corresponding VCG data to be deleted exists in the VCG management apparatus 120 (S418). At this time, the search of the VCG data is to check whether there is VCG data stored in the VCG management device 120 by checking the VCG number field 301 and the D field 307 of the VCG data. It is determined whether the corresponding VCG data exists in the VCG management device 120 (S419). If not, the deletion error message is transmitted to the operating system and the other device 230 (S420). Check the setting direction of the VCG from the D field 307 of (S421). If it is bidirectional (addDrop), the data of the VCG channel that can drop and add the VCG can be generated and set as a bidirectional channel in hardware. If the one-way direction is add, the data of the VCG channel to which the VCG can be added is generated (S424). If the one-way direction is drop, the data of the VCG channel to drop the VCG is generated (S425). The VCG channel data generation information generated as described above is stored in the VCG management apparatus 120 (S426). Then, it is determined whether to continue to drive the VCG management apparatus 120 (S427), and if not continue to terminate the VCG information that is set again from the operating system and the other device 230 when continuing to drive Wait to receive (S402).

5 is a flowchart illustrating a process of modifying VCG channel data in the VCG management apparatus of the EOS transmission apparatus according to the present invention.

Referring to FIG. 5, when VCG channel data stored in the VCG management apparatus 120 is modified according to VCG information set by an operator in the VCG management apparatus 120, the VCG number field 301 of the VCG channel data to be modified. Read the D field 307 and check whether the VCG channel data exists in the VCG management apparatus 110 (S501 and S502). If the VCG channel data does not exist in the VCG management apparatus 110, the process proceeds to step A of FIG. 4 to perform the VCG channel data generation process. If the VCG channel data exists in the VCG management apparatus 110, the S field 303 of the VCG channel data is read to determine whether the VCG state is changed (S503). After modifying the S field 303 and delivering the result to the hardware (S504), the LCAS field is checked (S505). Here, if the S field 303 of the stored VCG channel data and the S field of the VCG channel data set by the operator in step S503 are the same (that is, the VCG state is not changed), the S of the stored VCG channel data Proceed to step S505 without modifying the field 303.

In step S505, it is determined whether the L field 304 has been modified by reading the L field 304 indicating enable or disable of the LCAS from the VCG channel data (S505). If the L field 304 is modified, the VCG management apparatus 120 deletes the VCG channel set in the current hardware (S511), and deletes the VCG channel data deletion information corresponding to the deleted VCG channel (120). In operation S512, the process proceeds to A of FIG. 4 to generate a new VCG with a value corresponding to the modified L field 304, and performs a VCG channel data generation process (S404). At this time, the deletion of the VCG, as in step S418 of FIG. 4, deletes the corresponding VCG by reading the D field 307 of the VCG channel data capable of reading the direction information of the VCG.

If the L field 304 is not modified in step S505, the T field 305 indicating whether a payload type is VC3 or VC4 is read from the VCG channel data, and the T field 305 of the VCG channel data. It is determined whether the) has been modified (S506). If the T field 305 is modified, the VCG management apparatus 120 deletes the VCG channel set in the current hardware (S511), and deletes the VCG channel data deletion information corresponding to the deleted VCG channel. In operation S512, the process proceeds to A of FIG. 4 to generate a new VCG with a value corresponding to the modified T field 304, and performs VCG channel data generation (S404).

If the T field 305 is not modified in step S506, it is determined whether a Payload FCS Indicator (PFI) header, which is a function of checking a frame check sequence (FCS) in the VCG channel data, is enabled or disabled. The P field 306 is read to determine whether the P field 306 of the VCG channel data has been modified (S507). If the P field 306 is modified, the VCG management apparatus 120 deletes the VCG channel set in the current hardware (S511), and deletes the VCG channel data deletion information corresponding to the deleted VCG channel. In operation S512, the process proceeds to A of FIG. 4 to generate a new VCG with a value corresponding to the modified P field 304, and performs a VCG channel data generation process (S404).

If the P field 306 has not been modified in step S507, addDrop if the bidirectional or unidirectional direction of the VCG setting by the operator in the VCG channel data is dropped, and if it is unidirectional, it is dropped. And reading the D field 307 indicating the add to determine whether the D field 307 of the VCG channel data has been modified (S508). If the D field 307 is modified, the VCG management apparatus 120 deletes the VCG channel set in the current hardware (S511), and deletes the VCG channel data deletion information corresponding to the deleted VCG channel. In step S512, the process proceeds to A of FIG. 4 to generate a new VCG with a value corresponding to the modified D field 304, and performs a VCG channel data generation process (S404).

If the D field 304 is not modified in step S508, the VCG management apparatus 210 determines that the timeslot 311 is modified to determine whether the LCAS is enabled (S509), and the LCAS. Is enabled, the VCG channel data is transmitted to the LCAS controller 170 (S513), and the LCAS controller 170 is operated as shown in FIG. 6 to fit the modified Timeslot 311. The VCG channel data modification information is stored in the VCG management apparatus 120 (S510). If the LCAS is disabled in step S509, since the modification of the timeslot 311 of the VCG in which the LCAS is disabled is not a VCG modification for dynamic bandwidth allocation, the corresponding VCG is deleted (S511). ), After storing VCG channel data deletion information corresponding to the deleted VCG channel in the VCG management device 120 (S512), proceed to A of FIG. 4 to generate a new VCG to perform the VCG channel data generation process. (S404).

6 is a flowchart illustrating a VCG management method performed by the LCAS controller using VCG data of the VCG management apparatus in the EOS transmission apparatus according to the present invention.

Referring to FIG. 6, first, the LCAS controller 170 is operated (S601), and the VCG management apparatus 120 shown in FIG. 5 processes the VCG channel data when the LCAS is enabled according to the modification of the VCG channel data. It is determined whether to perform the process (S510) or whether to perform a process for the dynamic bandwidth allocation service due to the VCG failure detection in the failure detection unit 130 (S602).

As a result of the determination in step S602, when the VCG channel data processing process received from the VCG management apparatus 120 shown in FIG. 5 is to be performed, the VCG management apparatus 120 reads the VCG channel data (S603). In this case, the LCAS controller 170 initializes a register necessary for the dynamic bandwidth allocation service by the VCG data set by the operating system and the other device 110 (S604). The register consists of a previous time slot (preTimeslot), a current time slot (curTimeslot), a previous position (prePos), the current position (curPos), the previous number (preNum) and the current number (curNum), the previous time slot ( preTimeslot) is a VCG timeslot 311 currently performing LCAS dynamic bandwidth allocation service and a current timeslot (curTimeslot) is delivered from the VCG management device 210 to perform a new dynamic bandwidth allocation service. Activated Timeslots (313). Also, preNum is the number of timeslots 311 allocated to the hardware VCG channel, and curNum is the number of timeslots 311 to be allocated for the current dynamic bandwidth service. prePos) is an index for processing a preTimeslot in the LCAS controller 170, and a current position (curPos) is an index of a curTimeslot, and each of these values is initialized to zero.

Subsequently, it is determined whether to continue the dynamic bandwidth allocation by the VCG management apparatus 120 (S606), and the previous position (prePos) and the current position (curPos), which are indexes of the timeslot 311 to be processed, remain. If not, it is determined whether the LCAS controller 170 continues to operate (S620). If it does not continue to operate, it terminates and if it continues to operate, it waits to receive data input from the VCG management apparatus 120 or the failure detection unit 130 (S602). ).

In the step S606, if the previous position (prePos) or the current position (curPos), which is an index to be processed for dynamic bandwidth allocation, remains in the current position (prePos) time slot 311 and the current time of the previous time slot (preTimeslot) It is determined whether the value of the current position (curPos) th time slot 311 of the slot (curTimeslot) is the same (S607), and if it is the same, the index numbers of the previous position (prePos) and the current position (curPos) are increased (S608). It is determined whether to continue the next dynamic bandwidth allocation service (S606).

Subsequently, it is determined whether the prePos index is greater than or equal to the previous number preNum, which is the number of timeslots 311 of the current hardware VCG channel (S609). In this case, it is determined that the dynamic bandwidth is allocated and the current position (curPos) th time slot 311 of the current time slot (curTimeslot) is added to the active timeslots 313 of the current hardware VCG channel. add (S610), the index number of the current position (curPos) is increased (S611), and it is determined whether to continue the dynamic bandwidth allocation service (S606).

As a result of the determination in step S609, when the previous position (prePos) is still smaller than the current number (preNum), it is determined whether the reduction of the dynamic bandwidth allocated to the current VCG is necessary (S612). When the previous time slot (prePos) of the previous time slot (preTimeslot) allocated to the dynamic bandwidth is deleted (S613) and the index number of the previous position (prePos) is increased (S614) It is determined whether to continue the allocation service (S606).

 In addition, if it is determined that the dynamic bandwidth allocation by the fault detection unit 130 should be performed instead of the dynamic bandwidth allocation by the VCG management device 120 (S602), all faults generated by the fault detection unit 260 are read ( S615) After determining that there is a failure to be processed after processing the failure (S616), if all failures have been handled, it is determined whether the LCAS controller 170 should continue to operate (S620). As a result of the determination in step S616, if there is a failure to be processed, the VCG management device 120 searches for the VCG number field 301 set to the timeslot 311 where the failure occurs (S617). In addition, the bandwidth is reduced in the dynamic bandwidth allocation service of the searched timeslot 311 of the VCG (S618), and the active timeslots 313 of the VCG stored in the VCG management apparatus 120 are modified (S619). The dynamic bandwidth allocation process by the fault detection unit 260 is performed until it is determined that all faults have been dealt with (S616).

As such, in the conventional VCG management apparatus, the VCG configuration information is set from the operating system and the other apparatus 110 without software management, and dynamic bandwidth allocation by service and failure detection according to the LCAS operation is associated with the software VCG management apparatus. In the present invention, in the present invention, the VCG management apparatus 120 creates VCG information to define VCG data in software, and divides the VCG set by the operator into a VCG number field 301 and a D field 307. Manage by creating, modifying and deleting with VCG data.

Furthermore, it is possible to configure the value of the field of the VCG data according to the VCG setting and operate according to the field value, and the LCAS controller 170 may also share the VCG data managed by the VCG management device 120, thereby allowing the dynamic by the operator. Dynamic bandwidth allocation by the bandwidth allocation and failure detection unit 130 is enabled.

Although the accompanying drawings of the present invention have been described above, it shows a flowchart of an embodiment of the present invention and does not limit the present invention. Therefore, anyone with this technical knowledge can improve various functions and the like without departing from the scope of the technical idea of the present invention.

In the VCG management method of the EOS transmission apparatus according to the present invention, VCG data is defined and managed in software compared to the conventional VCG management method, and coherent and efficient dynamic bandwidth allocation is possible in connection with the LCAS controller.

In addition, the operator can operate the VCG configuration more reliably and can easily analyze the bandwidth change because the bandwidth allocation of the VCG changed by the failure occurring in the SONET / SDH interface is modified in the VCG data of the VCG management apparatus.

Claims (22)

A first step of receiving VCG information set by an operator in the VCG management apparatus; A second step of defining and receiving the received VCG information as VCG data; Setting the VCG data as a VCG channel in a SONET / SDH interface; And A fourth step of creating, modifying, and deleting data on the set VCG channel according to the VCG information set by the operator to manage the corresponding VCG; VCG management method in the EOS transmission device comprising a. The method of claim 1, wherein the fourth step, Determining whether to generate, modify, and delete the VCG channel data according to the VCG information set by the operator; And Storing the created, modified, and deleted VCG channel data; VCG management method in the EOS transmission device characterized in that it further comprises. The method of claim 1, wherein the VCG channel data, A field for identifying a corresponding VCG, a field indicating a timeslot of the VCG, a field indicating a failure of the time slot, a field indicating a state of a timeslot due to the failure of the time slot, the time slot state, A field indicating the number of failures and their timeslots in the VCG, a field indicating the state of the VCG, a field indicating whether the LCAS is enabled or disabled, a field indicating the payload type of the VCG, the FCS of the VCG Field indicating whether the payload FCS indicator (PFI) header for checking (Frame Check Sequence) is enabled or disabled, a field indicating directionality of the VCG set by the operator, a field indicating the VCG failure, and a function to be added later VCG management method in the EOS transmission device, characterized in that it comprises an unused field prepared for. The method of claim 3, wherein the timeslot, Characterized in that the VCG is divided into provisioned timeslots indicating the number of timeslots of the first timeslots of the timeslot and active timeslots indicating the number of timeslots of the later timeslots. How to manage VCG in EOS transmission device. The method of claim 1, wherein the generation of the VCG channel data of the fourth step, Checking the directionality of the VCG set by the operator; Generating data for a VCG channel that drops and adds a VCG if the VCG's directionality is bidirectional; Generating data for a VCG channel dropping or adding a VCG according to drop or add if the VCG is unidirectional; And Storing the generated VCG channel data in a VCG management apparatus; VCG management method in the EOS transmission device comprising a. The method of claim 1, wherein the modification of the VCG channel data of the fourth step, Searching in the VCG management apparatus using an identifier and directionality of VCG channel data to be modified according to the VCG information set by the operator; And Modifying the VCG channel data if there is VCG channel data to be corrected in the VCG management apparatus as a result of the search; VCG management method in the EOS transmission device comprising a. The method of claim 6, wherein the modification of the VCG channel data, Determining whether each VCG state information of the VCG information set by the operator and the VCG channel data to be modified has changed; Changing VCG state information of the VCG channel data to be modified if it is changed; Determining whether LCAS state information, payload type information, PFI information, and directional information of the VCG are respectively modified in the VCG channel data; Deleting the VCG channel set in the current hardware, and storing VCG channel data deletion information corresponding to the deleted VCG channel in the VCG management apparatus if it has been modified; Determining if LCAS is enabled if not modified; And If it is not enabled, deleting the VCG channel set in the current hardware and storing VCG channel data deletion information corresponding to the deleted VCG channel in the VCG management apparatus; VCG management method in the EOS transmission device comprising a. The method of claim 1, wherein the deletion of the VCG channel data of the fourth step, Searching by the VCG management apparatus using an identifier and a direction in the data of the VCG channel to be deleted according to the VCG information set by the operator; And Checking directionality of the VCG set by the operator when VCG channel data to be deleted exists in the VCG management apparatus as a result of the search; Deleting data for a VCG channel dropping and adding a VCG if the VCG has a bidirectional direction; Deleting data for a VCG channel dropping or adding a VCG according to whether the VCG is unidirectional if the VCG is unidirectional; And Storing the deleted VCG channel data information in a VCG management apparatus; VCG management method in the EOS transmission device comprising a. The method of claim 1, wherein when generating VCG channel data in the fourth step, Reading a field indicating an LCAS state of the generated VCG channel data and allocating a dynamic bandwidth to a timeslot corresponding to activated timeslots when the LCAS is enabled; VCG management method in the EOS transmission device characterized in that it further comprises. The method of claim 9, Detecting whether a failure occurs in the VCG channel of the SONET / SDH interface; Correcting a timeslot according to the failure when a failure is detected in the VCG channel; VCG management method in the EOS transmission device characterized in that it further comprises. The method of claim 10, wherein the failure of the VCG channel, Lost frame sync (LFS), core hec error (CHEC), frame check sum error (FCS), group id error (GRPID), MFI unlock (MFI), sequence number mismatch (SEQM), not aligned before writing on path VCG (Message CRC error), State Machine Fail (SMFL) and RXMST (Rx_MST) at least one selected from the VCG management method in the EOS transmission apparatus. The method of claim 1, wherein the SONET / SDH interface, STS_48L, STS_12L, STS_192L, STM_64, STM_16, VC3, VC4, STS_1L, STS_1P, STS_3L, STS_3cP, STS_12cP, STS_48cP, STS_192cP, STM_0, STM_1, VC4_4c, VC4_16c, VC4_64c, VC4_16c, VC4_64c How to manage VCG on your device. A first step of receiving VCG information set by an operator in the VCG management apparatus; A second step of defining and receiving the received VCG information as VCG data; Setting the VCG data as a VCG channel in a SONET / SDH interface; A fourth step of allocating a dynamic bandwidth to a timeslot corresponding to an active timeslot when LCAS of the set VCG channel is enabled; Determining whether the VCG channel data can be modified or set as a new VCG channel without deleting the VCG channel set in hardware when the VCG channel is modified; A sixth step of performing dynamic bandwidth allocation by transferring corresponding VCG channel data to an LCAS controller when there is a change in the active timeslot of the VCG channel; And A seventh step in which the LCAS controller determines the time slot to be deleted and the time slot to be added and dynamically corrects the bandwidth allocation for the dynamic bandwidth allocation set by the operator; VCG management method in the EOS transmission device comprising a. The method of claim 13, wherein the VCG channel data, A field for identifying a corresponding VCG, a field indicating a timeslot of the VCG, a field indicating a failure of the time slot, a field indicating a state of a timeslot due to the failure of the time slot, the time slot state, A field indicating the number of failures and their timeslots in the VCG, a field indicating the state of the VCG, a field indicating whether the LCAS is enabled or disabled, a field indicating the payload type of the VCG, the FCS of the VCG Field indicating whether the payload FCS indicator (PFI) header for checking (Frame Check Sequence) is enabled or disabled, a field indicating directionality of the VCG set by the operator, a field indicating the VCG failure, and a function to be added later VCG management method in the EOS transmission device, characterized in that it comprises an unused field prepared for. The method of claim 13, wherein the timeslot, Characterized in that the VCG is divided into provisioned timeslots indicating the number of timeslots of the first timeslots of the timeslot and active timeslots indicating the number of timeslots of the later timeslots. How to manage VCG in EOS transmission device. The method of claim 13, wherein the third step, And the VCG channel is set according to the identifier and the directionality of the corresponding VCG channel according to the generated VCG data. The method of claim 16, wherein the third step, The directionality of the VCG channel is divided into bidirectional and unidirectional, Generating data for a VCG channel that drops and adds in both directions; And Generating data for a VCG channel dropping or adding a VCG according to a drop or add when the VCG is unidirectional; VCG management method in the EOS transmission device comprising a. The method of claim 13, Detecting whether a failure has occurred in the VCG channel; Confirming whether the VCG channel has failed in the LCAS controller; And Modifying a timeslot according to dynamic bandwidth allocation due to the failure due to a failure in the VCG channel; VCG management method in the EOS transmission device characterized in that it further comprises. The method of claim 18, wherein the failure of the VCG channel, Lost frame sync (LFS), core hec error (CHEC), frame check sum error (FCS), group id error (GRPID), MFI unlock (MFI), sequence number mismatch (SEQM), not aligned before writing on path VCG (Message CRC error), State Machine Fail (SMFL) and RXMST (Rx_MST) at least one selected from the VCG management method in the EOS transmission apparatus. The method of claim 13, wherein the SONET / SDH interface, STS_48L, STS_12L, STS_192L, STM_64, STM_16, VC3, VC4, STS_1L, STS_1P, STS_3L, STS_3cP, STS_12cP, STS_48cP, STS_192cP, STM_0, STM_1, VC4_4c, VC4_16c, VC4_64c, VC4_16c, VC4_64c How to manage VCG on your device. The VCG management device that creates and manages VCG information set by the operator as VCG data, the failure detection unit that detects the failure of the VCG channel, and the LCAS technique are applied to share the VCG data with the VCG management device, thereby providing dynamic management by the operator. In the VCG management method in an EOS transmission apparatus including an LCAS controller that performs VCG bandwidth allocation in software, Determining whether the LCAS of the VCG channel is enabled or whether a failure is detected in the VCG channel; If the LCAS of the VCG channel is enabled, reading the channel data stored in the VCG management apparatus from the LCAS controller and initializing a register necessary for dynamic bandwidth allocation by the VCG channel data set by the operator; Determining whether a previous position (prePos) or a current position (curPos) of a timeslot to be processed for dynamic bandwidth allocation remains; If it remains, it is determined whether the value of the current position (prePos) time slot of the previous time slot and the current position (curPos) time slot of the current time slot (curTimeslot) is equal, and if it is the same, the previous position (prePos) and the current position (4) increasing the index number of (curPos) to the third step; If it is different in the fourth step, it is determined whether the previous position (prePos) is greater than or equal to the previous number (preNum), which is the number of timeslots of the current hardware VCG channel. In this case, the current position (curPos) th time slot of the current time slot (curTimeslot) is added to the active timeslots of the current hardware VCG channel, and the index number of the current position (curPos) is determined. A fifth step of increasing the number to proceed to the third step; In the fifth step, when the time slot is to be subtracted by determining whether the reduction of the dynamic bandwidth allocated to the current VCG is necessary, the time before the previous position (prePos) of the previous time slot (preTimeslot) previously allocated to the dynamic bandwidth is generated. A sixth step of deleting the slot and increasing the index number of the previous position (prePos) to proceed to the third step; A seventh step of determining whether to continue driving the LCAS controller if a previous position (prePos) or a current position (curPos) of the timeslot to be processed for dynamic bandwidth allocation remains in the third step; VCG management method in the EOS transmission device comprising a. The method of claim 21, If a failure is detected in the VCG channel in the first step, reading the detected failure from the failure detection unit, and retrieving the VCG channel of the timeslot in which the failure occurs in the VCG management apparatus; Dynamically reducing the bandwidth of the retrieved VCG timeslots and modifying active timeslots of VCGs stored in the VCG management apparatus; And Repeating the above steps until dynamic bandwidth allocation is performed for all faults generated by the fault detection unit; VCG management method in the EOS transmission device characterized in that it further comprises.

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