KR100912954B1 - Device for transmission convergence layer of gigabit capable passive optical network - Google Patents

Abstract

The present invention provides a transmission convergence layer device for a gigabit passive optical network. The transmission convergence layer device for a gigabit passive optical network includes a transmission path coding unit for preventing communication of users other than the subscriber, a media access control unit for framing or deframing data corresponding to the OSI 2 layer. A data processing unit for compressing 3.0 Gbps data into 2.5 Gbps data or restoring the data to 3.0 Gbps data, a data queue unit for processing according to priority processing for each service, and a port aggregation unit for dividing data into 1 Gbps data And a plurality of Ethernet media access controllers receiving 1 Gbps of data.

Gigabit Passive Optical Networks, Transport Convergence Layer, IEEE 802.1P

Description

Device for transmission convergence layer of gigabit capable passive optical network

TECHNICAL FIELD The present invention relates to a Transmission Convergence Layer (TCL) device for a gigabit capable passive optical network (GPON), and more particularly to an optical line termination (OLT) and an optical network. The present invention relates to a transmission convergence layer device for a gigabit passive optical network, which is embedded in an optical network unit (ONT) and can effectively perform a transmission convergence layer function.

In the passive optical network system, as illustrated in FIG. 1, a signal transmitted downward through an optical cable connected to the optical transmission device 10 is split into a maximum of 64 stranded optical cables 20 while passing through a splitter. It can broadcast to the optical network units 31 and 32.

On the contrary, the signals transmitted by the plurality of optical network units 31 and 32 are multiplexed onto one optical cable 20 through a combiner and transmitted to the optical transmission device 10. FTTCab (Fiber-to-the-Cabinet), FTTC (Fiber-to-the-Curb), FTTB (Fiber-to-the-Building), etc., depending on the installation location and processing capacity of the optical network units 31 and 32 Can be used.

On the other hand, a device that performs a transmission convergence layer function that handles the inherent functions of the passive optical network is essential for the passive optical network system. Devices performing such a transmission convergence layer function transmit at different data rates. For example, in a gigabit passive optical network system, a device performing a transmission convergence layer function transmits data at 2.5 Gbps or at 3.0 Gbps.

However, in the conventional gigabit passive optical network system, the device performing the transmission convergence layer function discards 500 Mbps data among 3.0 Gbps data or 3.0 Gbps in order to match the data rate of 2.5 Gbps and the data rate of 3.0 Gbps. The data rate is adjusted to a data rate of 2.5 Gbps, so the convergence layer function could not be effectively performed.

Accordingly, an object of the present invention is to provide a transmission convergence layer device for a gigabit passive optical network, which can effectively perform a transmission convergence layer function in a gigabit passive optical network system.

Technical problems to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

The transmission convergence layer device for a gigabit passive optical network according to an embodiment of the present invention for achieving the above technical problem is a parity for mixing 2.5 Gbps of data, recovering the mixed data, and detecting errors in the data. A transmission path coding unit for determining an error by comparison, recovering an error on the optical channel by using a Reed-Solomon code, and preventing a user other than a subscriber from communicating, and OSI 2 of data received from the transmission path coding unit A media access control unit for framing or deframing data corresponding to a layer, framing or deframing data corresponding to an OSI 2 layer, and transmitting the same to the transmission path coding unit; and 3.0 Gbps data is compressed into 2.5 Gbps data and transmitted to the media access control unit, or to the media access control unit. Data processing unit for restoring data received from the data processing unit to 3.0 Gbps data, and processing the data received from the data processing unit according to the priority processing order for each service, or processing the data according to the priority processing order for each service and transmitting the data to the data processing unit. A data queue section, a port aggregation section for dividing and receiving data received from the data queue section into 1 Gbps data, or collecting and sending a plurality of 1 Gbps data to the data queue section, and 1 Gbps from the port aggregation section. It includes a plurality of Ethernet media access control to receive the data of.

A transmission convergence layer element for a gigabit passive optical network according to an embodiment of the present invention has a first priority in which the data processor classifies data received from the medium access controller into eight types according to a service type packet by IEEE 802.1P. A processing priority classifier, and a data restorer for restoring packets, except for IP (Internet Protocol) broadcasting packets and Internet telephony packets, out of eight packets classified from the first priority processing classifier to 3.0 Gbps packets, and the first priority. The first packet multiplexing unit receives an IP broadcast packet and an Internet telephony packet from a processing rank classifier, receives 3.0 Gbps packets restored from the data decompressor, multiplexes the classified packets into a series of packets, and transmits them to the data queue unit. And a type of service based on IEEE 802.1P for data received from the data queue unit. The second priority classifier classifying the packet into eight types according to the packet and the packet except the Internet protocol (IP) broadcast packet and the Internet telephone packet among the eight packets classified from the second priority processing classifier are packets of 2.5 Gbps. Receive the IP broadcast packet and the Internet telephony packet from the second priority processing classifier, receive the compressed 2.5 Gbps packets from the data compressor, and multiplex the classified packets into a series of packets. And a second packet multiplexer for transmitting to the media access control.

In addition, the transmission convergence layer element 100 for a gigabit passive optical network according to an embodiment of the present invention, the data processing unit, the traffic for detecting whether the packet transmitted from the second packet multiplexer is compressed to 2.5 Gbps A capacity analyzer and a flow control packet which receives a sensed signal from the traffic capacity analyzer and reduces the amount of data transmission in the data queue part when the traffic capacity analyzer detects that the traffic capacity analyzer is not compressed to 2.5 Gbps. It is preferable to further include a flow controller.

A transmission convergence layer device for a gigabit passive optical network according to an embodiment of the present invention made as described above needs to discard data or adjust the data transmission speed by compressing and transmitting 3.0 Gbps data into 2.5 Gbps data. Therefore, the transmission convergence layer function can be effectively performed in a gigabit passive optical network system.

Specific details of other embodiments are included in the detailed description and the drawings. Advantages and features of the present invention, and methods for achieving them will be apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. Like reference numerals refer to like elements throughout.

Referring to FIG. 2, a transmission convergence layer element 100 for a gigabit passive optical network according to an embodiment of the present invention will be described. 2 is a block diagram of a transmission convergence layer device 100 for a gigabit passive optical network according to an embodiment of the present invention.

As shown in FIG. 2, the transmission convergence layer device 100 for a gigabit passive optical network according to an embodiment of the present invention includes a transmission path coding unit 110, a medium access control unit 120, a data processing unit 130, The data queue unit 140, the port aggregation unit 150, and the Ethernet medium access control unit 161 to 163 are included.

The transmission path coding unit 110 scrambles or recovers the mixed data of 2.5 Gbps photoelectrically converted. This mixing of data is performed to prevent this because it is difficult to extract the clock when 1 or 0 lasts a long time.

In addition, the transmission path coding unit 110 transmits the result of the operation after the bit interleaved parity (BIP) operation in addition to the designated position to detect an error in the data, and calculates the parity at the time of reception to transmit the result value. Determine whether there is an error by comparing with the result of operation in.

In addition, the transmission path coding unit 110 transmits an operation result value by using a Reed-Solomon code, and recovers an error on the optical channel with the operation result value (FEC).

Meanwhile, the transmission path coding unit 110 performs an advanced encryption standard (AES) that prevents communication of subscribers other than subscribers.

The media access control unit 120 may framing or deframing data corresponding to an OSI (Open Systems Interconnection) layer 2 among the data received from the transmission path coding unit 110, and thereby, the data processing unit 130. The data corresponding to the OSI 2 layer among the data transmitted from the data processor 130 or the data is transmitted to the transmission path coding unit 110 by framing or deframing.

The data processor 130 compresses 3.0 Gbps of data transmitted from the data queue unit 140 to 2.5 Gbps of data and transmits the data to the media access control unit 120, or transmits data received from the media access control unit 120. It restores to 3.0 Gbps of data and transmits it to the data queue part 140. FIG. Here, 3.0 Gbps of data is converted into 2.5 Gbps of data by lossless compression.

The data queue unit 140 processes the data received from the data processing unit 130 according to the priority processing order for each service, transmits the data to the port junction unit, or processes the data transmitted from the port junction unit according to the service priority sequence for each service. Send to processor 130.

The port aggregation unit 150 divides the data received from the data queue unit 140 into data of 1 Gbps and transmits the data to the plurality of Ethernet media access controllers 161 to 163 or the plurality of Ethernet media access controllers 161 to 163. ) Collects a plurality of 1 Gbps data transmitted from) and transmits the data to the data queue unit 140.

The plurality of Ethernet media access controllers 161 to 163 receive 1 Gbps of data from the port aggregation unit 150.

Referring to FIG. 3, the data processor 130 of the transmission convergence layer element 100 for a gigabit passive optical network according to an embodiment of the present invention will be described. 3 is a detailed block diagram of the data processing unit 130 of the transmission convergence layer device 100 for a gigabit passive optical network according to an embodiment of the present invention.

The data processor 130 includes a first priority process classifier 131, a data decompressor 132, a first packet multiplexer 133, a second priority process classifier 136, and a data compressor 135. ), And a second packet multiplexer 136.

The first priority processing classifier 131 classifies data received from the media access control unit 120 into eight types according to the service type packet according to the IEEE 802.1P, and the IP (Internet Protocol) broadcast packet and the Internet phone packet are first classified. The packet is transmitted to one packet multiplexer 133 and the rest is transmitted to the data decompressor 132. Since the Internet Protocol (IP) broadcast packet and the Internet telephony packet are already restored to 3.0 Gbps or are very sensitive to packet delay time, the first packet multiplexer 133 does not go through the data decompressor 132. It is desirable to transmit.

The data restorer 132 restores the packets except for the IP (Internet Protocol) broadcast packet and the Internet telephony packet among the eight packets classified from the first priority classifier 131 to the packets of 3.0 Gbps. Transmit to packet multiplexer 133.

The first packet multiplexer 133 receives the IP broadcast packet and the Internet telephony packet from the first priority process classifier 131, and receives the 3.0 Gbps packets restored from the data decompressor 132, thereby classifying the packet. These signals are multiplexed into a series of packets and transmitted to the data queue unit 140. In this case, processing is performed according to the priority processing order for each service.

The second priority processing classifier 136 classifies data received from the data queue unit 140 into eight types according to the service type packet by the IEEE 802.1P, and the IP (Internet Protocol) broadcast packet and the Internet telephone packet are classified into the second. The packet is transmitted to the packet multiplexer 136, and the rest are transmitted to the data compressor 135. Since Internet Protocol (IP) broadcast packets and Internet telephony packets are already compressed at 2.5 Gbps or are very sensitive to packet delay time, they are sent directly to the second packet multiplexer 136 without going through the data compressor 135. It is desirable to.

The data compressor 135 compresses the packets except for the Internet Protocol (IP) broadcast packet and the Internet telephony packet among the eight packets classified from the second priority processing classifier 136 into packets of 2.5 Gbps, thereby multiplying the second packet. Send to firearm 136.

The second packet multiplexer 136 receives the IP broadcast packet and the Internet telephony packet from the second priority classifier 136, receives the compressed 2.5 Gbps packets from the data compressor 135, and receives the classified packets. The packet is multiplexed into a line of packets and transmitted to the media access control unit 120. In this case, processing is performed according to the priority processing order for each service.

In some cases, the data processor 130 may further include a traffic capacity analyzer 137 and a flow controller 138.

The traffic capacity interpreter 137 detects whether a packet transmitted from the second packet multiplexer 136 has been compressed to 2.5 Gbps, and the flow controller 138 indicates that the traffic capacity interpreter 137 has not been compressed to 2.5 Gbps. In case of sensing, the sensing signal is received from the traffic capacity analyzer 137 to transmit a flow control packet requesting to reduce the data transmission amount of the data queue unit 140.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains may be embodied in other specific forms without changing the technical spirit or essential features of the present invention. I can understand that.

Therefore, since the embodiments described above are provided to fully inform the scope of the invention to those skilled in the art, it should be understood that they are exemplary in all respects and not limited. The invention is only defined by the scope of the claims.

1 is a block diagram of a typical passive optical network system.

2 is a block diagram of a transmission convergence layer device for a gigabit passive optical network according to an embodiment of the present invention.

3 is a detailed block diagram of a data processor of a transmission convergence layer device for a gigabit passive optical network according to an embodiment of the present invention.

 (Explanation of symbols for the main parts of the drawing)

110: transmission path coding unit

120: media transfer control

130: data processing unit

140: data queue section

150: port assembly

161 to 163: Ethernet medium access control

Claims (3)

Mixed 2.5 Gbps data, recovers mixed data, compares parity for detecting data errors, determines whether errors exist, recovers errors on Fiber Channel using Reed-Solomon codes, and users other than subscribers. Transmission line coding unit 110 to prevent communication; Framing or deframing data corresponding to OSI 2 layer among the data received from the transmission path coding unit 110, and framing or deframing data corresponding to OSI 2 layer A medium access control unit for transmitting to the transmission path coding unit 110; A data processor which compresses 3.0 Gbps of data into 2.5 Gbps of data and transmits the data to the media access control unit or restores data received from the media access control unit to 3.0 Gbps data; A data queue for processing data received from the data processing unit according to a priority processing order for each service or for processing data according to a priority processing order for each service and transmitting the data to the data processing unit;  A port aggregation unit for dividing and receiving data received from the data queue unit into 1 Gbps data, or collecting and transmitting a plurality of 1 Gbps data to the data queue unit; And And a plurality of Ethernet media access controllers receiving 1 Gbps of data from the port aggregation unit. The method of claim 1, wherein the data processing unit A first priority process classifier classifying data received from the medium access control unit into eight types according to a service type packet according to IEEE 802.1P; A data decompressor for restoring packets, except for IP (Internet Protocol) broadcast packets and Internet telephony packets, out of the eight packets classified from the first priority process classifier into 3.0 Gbps packets; Receiving an IP broadcast packet and an Internet telephony packet from the first priority classifier, receiving 3.0 Gbps packets restored from the data decompressor, multiplexing the classified packets into a series of packets, and transmitting them to the data queue unit. A first packet multiplexer; A second priority processing classifier for classifying data received from the data queue section into eight types according to a service type packet by IEEE 802.1P; A data compressor for compressing packets, except for IP (Internet Protocol) broadcasting packets and Internet telephony packets, out of eight packets classified from the second priority processing classifier into 2.5 Gbps packets; And Receiving an IP broadcast packet and an Internet telephony packet from the second priority processing classifier, receiving 2.5 Gbps of compressed packets from the data compressor, multiplexing the classified packets into a series of packets, and transmitting them to the media access control unit. Gigabit passive optical network transmission convergence layer element comprising a second packet multiplexer. The method of claim 2, wherein the data processing unit, A traffic capacity analyzer for detecting whether a packet transmitted from the second packet multiplexer is compressed to 2.5 Gbps; And If the traffic capacity analyzer detects that it is not compressed to 2.5 Gbps, the flow controller further receives a detection signal from the traffic capacity analyzer and transmits a flow control packet requesting to reduce the data transmission amount of the data queue part. And gigabit passive optical network transmission convergence layer device.

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