KR100919057B1 - Apparatus and method for GTC frame extraction of the GPON OLT - Google Patents

Abstract

The present invention relates to an uplink GTC frame extraction apparatus and method in an OLT apparatus of a gigabit passive optical network system. In an apparatus for extracting an uplink GTC frame in which OLT is bursted from a plurality of ONU / ONTs in a GPON system according to the present invention, an upband identifier (Alloc-ID) is extracted by extracting uplink allocation information included in a downlink GTC frame. ONUID table generation unit for outputting the ONUID value corresponding to the uplink transmission time control table storage unit for storing the extracted upband allocation information and the ONUID output value, and uplink allocation information received from the uplink transmission time control table storage unit A reset control unit for initializing an optical module to which a serial signal is input, and a reset controller at a time point initialized by the reset control unit, finds the start of an uplink GTC frame, and receives uplink allocation information from an uplink transmission time control table storage unit. The frame extracting unit generates length information of the GTC frame and thus extracts the uplink GTC frame. And it characterized in that.

GPON, OLT, ONU, OLT, Uplink GTC Frame, Downlink GTC Frame

Description

Apparatus and method for GTC frame extraction of the GPON OLT} in OLT apparatus of Gigabit passive optical network system

TECHNICAL FIELD The present invention relates to a passive optical subscriber network, and more particularly, to an apparatus and a method for accurately extracting a GTC frame of each ONU / ONTs received bursting upward in an OLT of a GPON system.

Recently, as an optical subscriber network technology for efficiently providing various multimedia contents, a passive optical network (hereinafter referred to as a PON) technology is used. PON technology has three standard methods, ITU, which is B-PON (Broadband PON or A-PON), G-PON (Gigabit PON), and (G) E-PON (Gigabit Ethernet PON). Standardization was done by -T and the Institute of Electrical and Electronics Engineers (IEEE). The B-PON aims to accommodate all existing telecommunication services, and divides and transmits all transmission data into ATM (Asynchronous Transfer Mode) cells. Such B-PON is not suitable for IP (Internet protocol) based service, and has a disadvantage of providing only up to 622Mbps of transmission bandwidth.

EPON provides up to 1Gbps transmission bandwidth up and down through low-cost Ethernet equipment. In addition, EPON efficiently provides IP service through a variable length Ethernet frame, but has a disadvantage in that a separate device must be installed to provide voice service.

G-PON, like B-PON, aims to accommodate all telecommunication services. However, the GEM (G-PON encapsulation method) is adopted to efficiently accommodate the Ethernet frame. Since the GEM frame is defined in the same period as the basic time unit of the conventional telecommunication service, it efficiently transmits an existing service such as a telephone or a leased line, and transmits without additional overhead. This GPON system consists of one optical line termination (OLT) and a number of optical network units (ONUs) consisting of point-to-multipoint.

Therefore, GPON transmission convergence (GTC) frames for GPON are logically transmitted downward to all ONU / ONTs (hereinafter referred to as ONTs). Upon receiving this, the ONTs extract the GEM frame and transmit it to the subscribers. On the other hand, in order for ONTs to transmit GTC frames for GPON upward, if any one ONT is transmitted, the remaining ONTs should not transmit GTC frames for GPON. This is to prevent collision due to transmission of GTC frames between ONTs.

Accordingly, in a link having a general PON structure, the OLT allocates a band or transmission time to ONTs. To this end, the OLT measures the distance at the time of registering the OLTs and adjusts them so that they reach the same time zone. When the transmission time is allocated to each OLT, each OLT can transmit data upward without collision with each other.

As such, in the GPON system using the PON structure, the GPON system allocates an uplink transmission band in bytes, and the OLT transmits transmission start byte information and transmission end byte information to the ONTs through the downlink GTC frame. Thereafter, the ONTs transmit data of the GTC frames to the OLT by the time allocated upward and the number of bytes allocated. Accordingly, the OLT should extract the data of the received GTC frames from the received ONTs, but there is a problem of knowing the information of the start and end of the GTC frames in order to accurately extract the received GTC frames.

The present invention is to solve this problem, as a number of ONU / ONT received the downlink GTC frame from the OLT of the GPON system to transmit the uplink GTC frame to the OLT burst, the OLT is bursting received uplink GTC frame It is an object of the present invention to provide an apparatus and method for accurately extracting a received uplink GTC frame by accurately initializing an optical module at a predetermined time of arrival to sense a signal at an accurate level.

Furthermore, an object of the present invention is to efficiently obtain the length information value of the extracted uplink GTC frame.

Furthermore, an object of the present invention is to efficiently extract PLOAM information and DBR information included in the extracted uplink GTC frame.

The above technical problem is achieved by the characteristic aspects of the present invention described below. In an apparatus for extracting an uplink GTC frame in which OLT is bursted from a plurality of ONU / ONTs in a GPON system according to the present invention, an upband identifier (Alloc-ID) is extracted by extracting uplink allocation information included in a downlink GTC frame. ONUID table generation unit for outputting the ONUID value corresponding to the uplink transmission time control table storage unit for storing the extracted upband allocation information and the ONUID output value, and uplink allocation information received from the uplink transmission time control table storage unit A reset controller for initializing an optical module to which a serial signal is input, and a delimiter at the time initialized from the reset controller, finds the start of an uplink GTC frame, and receives uplink allocation information from an uplink transmission time control table storage unit. The frame extracting unit generates length information of the uplink GTC frame and thus extracts uplink GTC frames. It is characterized by including.

According to this aspect of the present invention, an uplink GTC frame may be extracted and length information of the uplink GTC frame may be obtained.

The apparatus for extracting upward GTC frames according to an additional aspect of the present invention may further include a GTC frame demultiplexing processor configured to receive upward GTC frame information extracted from the frame extractor and extract PLOAM information and DBR information.

According to this aspect of the present invention, PLOAM information and DBR information included in the extracted uplink GTC frame may be extracted.

According to the present invention, by extracting and storing uplink allocation information included in the downlink GTC frame, the OLT may extract an effective range of the uplink GTC frame transmitted from the ONU / ONT. Accordingly, the present invention can be applied regardless of 10 Gbps GPON, 2.5 Gbps GPON, or 1 Gbps GPON system, and the hardware can be easily implemented in all GPON systems.

In addition, PLOAM and DBR information included in the extracted uplink GTC frame according to the present invention can be extracted, and since the estimated arrival time of the uplink GTC frame can be known in advance, the bursted uplink GTC frames can be easily initialized. It works.

The foregoing and further aspects of the present invention will become more apparent through the preferred embodiments described with reference to the accompanying drawings. Hereinafter, the present invention will be described in detail so that those skilled in the art can easily understand and reproduce the present invention through these embodiments.

1 is a block diagram showing a typical configuration of a PON.

As shown in FIG. 1, a general configuration of a PON has a tree structure in which one OLT corresponds to 1: N through a plurality of ONU / ONTs (hereinafter referred to as ONTs) and passive elements. Such OLT distributes downlink data frames to a plurality of ONTs through an optical distribution network (ODN). Multiple ONTs transmit the allocated downlink data frames to end user terminals.

Meanwhile, the data output from the end user terminals are uplink data frames, and a plurality of ONTs multiplex uplink data frames and transmit them to the OLT through the ODN. Such a GPON system constitutes 4K transmission containers (T-CONT), and operates in Asynchronous Transfer Mode (ATM) and GPON Encapsulation Method (GEM) modes, and the same T-CONT does not support both modes at the same time. . One ONT includes a plurality of T-CONTs, and the ONT allocates the uplink transmission band allocated from the OLT to the plurality of T-CONTs.

2 is a conceptual diagram illustrating a configuration of transmitting a GTC frame upward in a general GPON system.

As shown in FIG. 2, the GPON system continuously transmits the downlink GTC frame 10 at 125us periods. The downlink GTC frame 10 largely includes a frame header and a payload. The frame header includes SFC information, a PLOAM message, and uplink allocation information (US BW Map) 20. Uplink allocation information 20 includes Alloc-ID 21, Flag 23, Sstart 25, and End 27 information. The Alloc-ID 21 information indicates an identifier assigned to the T-CONT included in each ONT. The flag 23 is configured to determine whether to transmit PLOAM and DBR information in the uplink GTC frame 30.

The Sstart 25 information indicates the byte position at which ONTs with the corresponding Alloc-ID 21 start transmission. End 27 information indicates the location of the byte where the ONT with the corresponding Alloc-ID 21 completes the transmission. For example, T-CONT1 indicates an identifier of '1' and has byte position information starting transmission in Slot100 and ending transmission in Slot300. The payload of the downlink GTC frame 10 is a GEM frame is transmitted to the uplink GTC frame. Such a GEM frame typically consists of a GEM header and a GEM load region carrying packets up to 4,096 bytes in length.

The GEM header consists of PLI, PortID, Frag, and HEC. Here, the PLI is a field for indicating the length of the payload, and the PortID is a field for indicating an ID for identifying traffic in order to provide traffic multiplexing. Frag is a field for indicating a split state of a payload, and HEC is a field for header error detection and correction. The uplink GTC frame 30 receives the uplink GTC frame by an allocated byte size from the OLT. In this way, the OLT accurately extracts the uplink GTC frame 30 transmitted from the plurality of ONTs to enable the service.

3 is a diagram illustrating an uplink GTC frame structure transmitted upward in a GPON system.

As shown in FIG. 3, the uplink GTC frame 30 includes a physical layer overhead upstream (PLOu) 31, a physical layer operations, administration and management upstream (PLOAMu) 33, and a dynamic bandwidth report upstream (DBRu) 35. ), And payload 37 information. The payload 37 transmits GEM frames like the downlink GTC frame 10 described above. The PLOu 31 is composed of Pleamble 31-1, Delimiter 31-3, BIP 31-5, ONUID 31-7, and IND (Indication) 31-9.

Pleamble 31-1 is used as information for signal detection in the optical module, and is composed of patterns of '1' and '0'. Delimiter 31-3 is a parameter value indicating the start of an uplink GTC frame. Here, the Pleamble 31-1 and the Delimiter 31-3 use a value allocated from the OLT. The bit interleaved parity (BIP) 31-5 checks whether a bit error of the transmitted uplink GTC frame 30 has occurred. The ONUID 31-7 is used as an identifier of ONTs connected to the OLT transmitting the uplink GTC frame 30. The PLOAMu 33 performs a response to the PLOAM message transmitted from the OLT through the downlink GTC frame through the OLT. The DBRu 35 transmits size information of packets waiting to the T-CONT included in the ONTs.

Hereinafter, an apparatus for extracting an uplink GTC frame in a GPON system according to the present invention will be described in detail with reference to FIG. 4.

4 is a block diagram of an uplink GTC frame extraction apparatus in a GPON system according to an embodiment of the present invention.

As shown, the uplink GTC frame extracting apparatus includes an ONUID table generator 100, an uplink transmission time control table storage unit 200, a reset controller 300, and a frame extractor 400. The ONUID table generator 100 is configured to receive the uplink allocation information from the downlink GTC frame 10 and generate an ONUID output value. The ONUID output value generated by the ONUID table generator 100 may be represented by identifiers of ONTs connected to the OLT. The ONUID table generating unit 100 includes an allocation information extracting unit 110 according to an additional aspect of the present invention.

The allocation information extractor 110 extracts uplink allocation information included in the downlink GTC frame. Here, the extracted uplink allocation information includes an Alloc-ID 21, a Flag 23, an Sstart 25, and an End 27 as described above. Accordingly, the ONUID table generator 100 outputs the ONUID value through the Alloc-ID 21 and the ONUID information among the uplink allocation information extracted from the downlink GTC frame by the allocation information extractor 110. That is, the ONUID information is previously inputted to the Alloc-ID 21 information included in the uplink allocation information. Thereafter, when the Alloc-ID 21 is extracted through the allocation information extractor 110, the ONUID table generator 100 outputs an ONUID value from the extracted Alloc-ID 21. The uplink transmission time control table storage unit 200 stores the ONUID value generated from the ONUID table generator 100 and the uplink allocation information extracted from the allocation information extractor 110.

The reset controller 300 initializes the optical module at the time when the serial signal is input by referring to the uplink allocation information received from the uplink transmission time control table storage 200. The reset controller 300 initializes an optical module to which a serial signal is input by referring to the information of Sstart 25 among the uplink allocation information, wherein the PLO length, BCDR length, and serial of the uplink allocation information are serialized. Initialize considering the change time that is changed from signal to parallel signal. Here, the PLO (Physical layer overhead) length is the total length value of the Pleamble and Delimiter, the BCDR (Burst clock data recovery) length is the total time it takes to detect the serial signal in the optical module as a parallel signal. As described above, in the initialization of the reset control unit 300, since the PLO length and the BCDR length are not included in the Sstart 25 information, the reset control unit 300 is preferably initialized by reflecting this.

The frame extractor 400 obtains a point initialized from the reset controller 300 and receives uplink allocation information from the uplink transmission time control table storage 200 to generate length information of the uplink GTC frame 30. . Accordingly, the frame extractor 400 may extract the uplink GTC frame 30 according to an additional aspect of the present invention.

The frame extractor 400 according to an additional aspect of the present invention includes a delimiter searcher 410 and an END searcher 430. The delimiter search unit 410 is configured to find a time point initialized from the reset control unit 300, and may find a time point initialized using bit shifts in a parallel signal input from the optical module. Accordingly, when the initialized time point is found, the delimiter search unit 410 may acquire the start point of the uplink GTC frame 30.

The END search unit 430 is configured to find the end point of the uplink GTC frame 30 by referring to the END 27 information among the uplink allocation information received from the uplink transmission time control table storage unit 200. An end point of the uplink GTC frame 30 may be obtained using a formula.

Uplink GTC Frame Length = (Sstart Information-End Information) + 1

Accordingly, the frame extractor 400 may extract the uplink GTC frame and the length. Meanwhile, according to an additional aspect of the present invention, the END search unit 430 may filter the uplink GTC frame 30 received from the unwanted ONT by referring to the ONUID output value stored in the uplink transmission time control table storage unit 200. Can be. Accordingly, the END search unit 430 may extract only the desired uplink GTC frame 30.

According to a further aspect of the present invention, the uplink GTC frame 30 apparatus includes a GTC frame demultiplexing processor 500. The GTC frame demultiplexing processor 500 may receive flag 23 information from the END searcher 430 of the frame extractor 400 and extract PLOAM information and DBR information of the extracted uplink GTC frame 30. . As described above, the Flag 23 information includes a value for determining whether to transmit PLOAM and DBR information in the uplink GTC frame 30. Accordingly, the GTC frame demultiplexing processor 500 may extract the PLOAM information and the DBR information of the uplink GTC frame 30 with reference to the Flag 23 information.

Hereinafter, a method of extracting an uplink GTC frame in which a OLT is bursted from a plurality of ONTs in a GPON system according to an embodiment of the present invention will be described in detail with reference to FIG. 5.

5 is a flowchart of an uplink GTC frame extraction method according to an embodiment of the present invention.

As shown in FIG. 5, the OLT transmits a downlink GTC frame to multiple ONTs. Thereafter, the OLT receives uplink allocation information associated with the downlink GTC frame, and extracts fields included in the uplink allocation information when the uplink allocation information value is not '0' (S101). Here, the fields included in the uplink allocation information are Alloc-ID, Flag, Sstart, and End information. Thereafter, the OLT generates and stores the ONUID output value of the ONT through the Alloc-ID among the extracted upband allocation information (S103). That is, the ONUID information is previously inputted to the Alloc-ID information included in the uplink allocation information. When the Alloc-ID is extracted through the allocation information extracting unit, the OLT generates an ONUID output value from the extracted Alloc-ID and stores it in the uplink transmission time control table storage unit along with the extracted upband allocation information.

Thereafter, the OLT receives the uplink allocation information stored in the uplink transmission time control table storage unit and initializes the serial signal at the time when the serial signal is input to the optical module through the reset control unit by referring to the Sstart information (S105). As described above, the OLT is initialized at the time when the serial signal is input in consideration of the PLO length, BCDR length, and the change time changed from the serial signal to the parallel signal. Here, the PLO (Physical layer overhead) length is the total length value of the Pleamble and Delimiter, the BCDR (Burst clock data recovery) length is the total time it takes to detect the serial signal in the optical module as a parallel signal.

As described above, in the initialization of the reset control unit, the Sstart information does not include the PLO length and the BCDR length. Accordingly, the OLT obtains a point initialized from the reset controller through the frame extractor (S107). The frame extractor includes a delimiter searcher, and the delimiter searcher can find a time point initialized by using a bitwise shift in a parallel signal input to the optical module. As such, when the initialized time point is found, the start point of the uplink GTC frame related thereto may be found.

Thereafter, the OLT receives uplink allocation information from the uplink transmission time control table storage unit through the frame extractor and generates length information of the uplink GTC frame with reference to a start point of the uplink GTC frame (S109). Thereafter, the OLT extracts an end point of the uplink GTC frame through the frame extractor (S111). The frame extractor includes an END searcher, and the END searcher may find an end point of an uplink GTC frame by referring to END information of uplink allocation information received from the uplink transmission time control table storage. Accordingly, the OLT may extract the uplink GTC frame transmitted from the ONT.

Thereafter, the OLT receives the ONUID value of the extracted uplink GTC frame and the ONUID value stored in the uplink transmission time control table storage and compares the two ONUID values (S113). If the ONUID value of the extracted uplink GTC frame is different from the received ONUID value, the extracted uplink GTC frame is deleted (S115). If the two ONUID values match, the extracted uplink GTC frame is demultiplexed (S117). Accordingly, the unwanted uplink GTC frame received from the ONT may be filtered to extract necessary uplink GTC frames.

As such, according to the demultiplexing process, the OLT may extract the PLOAM information and the DBR information of the extracted uplink GTC frame by receiving the flag information through the GTC frame demultiplexing processing unit (S119 and S123). Here, the flag information includes a value for determining whether to transmit PLOAM and DBR information in the uplink GTC frame. If the PLOAM flag is '1', the OLT extracts PLOAM information from the uplink GTC frame (S123). In addition, if the DBR flag is '1', the OLT extracts DBR information from the uplink GTC frame (S125). Accordingly, the OLT may extract PLOAM and DBR information from the extracted uplink GTC frame.

So far I looked at the center of the preferred embodiment for the present invention.

Those skilled in the art will understand that the present invention may be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

According to the present invention, as a plurality of ONTs allocated a downlink GTC frame from an OLT in a gigabit passive optical network system transmits the GTC frame bursting upward to the OLT, the OLT extracts such a received uplink GTC frame by bursting. This can be used in the field of the optical network implemented.

1 is a block diagram showing a typical configuration of a PON,

2 is a conceptual diagram illustrating a configuration of transmitting a GTC frame upward in a typical GPON system;

3 is a structural diagram showing an uplink GTC frame structure transmitted upward in a GPON system;

4 is a block diagram of an uplink GTC frame extraction apparatus in a GPON system according to an embodiment of the present invention;

5 is a flowchart of a method of extracting an uplink GTC frame according to an embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

Downward GTC Frame: 10 Upward GTC Frame: 30

ONUID table generation unit: 100 Allocation information extraction unit: 110

Uplink Time Control Table Storage: 200 Reset Control: 300

Frame Extraction Unit: 400 Delimiter Search Unit: 410

END search part: 430 GTC frame demultiplexing part: 500

Claims (13)

A device for extracting an uplink GTC frame in which a OLT is received bursty from multiple ONU / ONTs in a GPON system: An ONUID table generation unit for receiving the uplink allocation information associated with the downlink GTC frame and generating an ONUID output value; An uplink transmission time control table storage unit for storing the received uplink allocation information and the generated ONUID output value; A reset control unit for initializing an optical module to which a serial signal is input by referring to uplink allocation information read from the uplink transmission time control table storage unit; A frame extracting unit obtaining a time point initialized from the reset control unit, receiving uplink allocation information from the uplink transmission time control table storage unit, generating length information of the uplink GTC frame, and extracting the uplink GTC frame accordingly; Uplink GTC frame extraction apparatus comprising a. The method of claim 1, wherein the ONUID table generating unit: And an allocation information extracting unit extracting the uplink allocation information associated with the downlink GTC frame. The uplink allocation information is uplink GTC frame extraction apparatus comprising Alloc-ID, Sstart, End, Flag information. The method of claim 1, wherein the ONUID table generating unit: And generating the ONUID output value by inputting ONUID information of the ONU / ONTs to Alloc-ID information included in the uplink allocation information. The method of claim 1, wherein the reset control unit: An optical module to which a serial signal is input is initialized with reference to the received uplink allocation information, and initialized in consideration of a PLO length and a BCDR length of the uplink allocation information and a change time changed from a serial signal to a parallel signal. Uplink GTC frame extraction apparatus, characterized in that. The apparatus of claim 1, wherein the frame extractor comprises: A delimiter searcher which finds a point initialized from the reset controller and thus finds a start point of an uplink GTC frame; An END searcher for finding an end point of the uplink GTC frame by referring to end information of the uplink allocation information stored in the uplink transmission time control table storage; Uplink GTC frame extraction apparatus comprising a. The method of claim 5, wherein the END search unit: And an uplink GTC frame received from an undesired ONU / ONT by referring to the ONUID output value stored in the uplink transmission time control table storage unit. The apparatus of claim 1, wherein the upward GTC frame extraction device comprises: A GTC frame demultiplexing processor which receives the uplink GTC frame information extracted from the frame extractor and extracts PLOAM information and DBR information; Uplink GTC frame extraction apparatus further comprises. A method of extracting an uplink GTC frame in which a OLT is received bursty from a plurality of ONU / ONTs in a GPON system: Receiving uplink allocation information associated with a downlink GTC frame, generating and storing an ONUID output value; Initializing an optical module to which a serial signal is input by referring to the uplink allocation information; Obtaining a point at which the optical module is initialized; Receiving the uplink allocation information and the point where the optical module is initialized, generating length information of the uplink GTC frame, and extracting the uplink GTC frame; Uplink GTC frame extraction method comprising a. 10. The method of claim 8, wherein generating and storing the ONUID output value comprises: Extracting the uplink allocation information associated with the downlink GTC frame; The uplink allocation information includes Alloc-ID, Sstart, End, Flag information, and generates the ONUID output value by inputting ONUID information of the ONU / ONTs to Alloc-ID information included in the uplink allocation information. Characterized by the uplink GTC frame extraction method. The method of claim 8, wherein initializing the optical module comprises: An optical module to which a serial signal is input is initialized with reference to the received uplink allocation information, and initialized in consideration of a PLO length and a BCDR length of the uplink allocation information and a change time changed from a serial signal to a parallel signal. Uplink GTC frame extraction method, characterized in that. The method of claim 8, wherein generating length information of the uplink GTC frame comprises: Finding an end point of the uplink GTC frame with reference to the received End information of the uplink allocation information; Uplink GTC frame extraction method comprising a. 12. The method of claim 11, wherein finding an end point of the upward GTC frame comprises: The uplink GTC frame extraction method of claim 1, wherein the uplink GTC frame received from an unwanted ONU / ONT is filtered by referring to the ONUID output value. 9. The method of claim 8, wherein the upward GRC frame extraction method is: Extracting PLOAM information and DBR information from the generated uplink GTC frame length information; Uplink GTC frame extraction method characterized in that it further comprises.

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