KR20120040048A - Efm bonding apparatus and dsl system having the same - Google Patents

Abstract

PURPOSE: An EFM(Ethernet in the First Mile) bonding apparatus and DSL(Digital Subscriber Line) system including the same are provided to increase communication speeds by embodying a CPE(Customer Premises Equipment) apparatus and a CO(Central Office) apparatus. CONSTITUTION: An EFM bonding execution input unit(310) outputs a fragmented ethernet frame. An output DSL port(320) changes signals of the fragmented ethernet frame. An input DSL port(330) changes a signal received by a copper telephone line into the signal of the fragmented ethernet frame. An EFM bonding execution output unit(340) restores the fragmented ethernet frame to an original ethernet frame.

Description

EFM bonding apparatus and DSL system including the same {EFM bonding apparatus and DSL system having the same}

The present invention relates to an EFM bonding apparatus, a DSL system including the same, and a control method thereof, and more particularly, to an EFM bonding apparatus capable of maximizing DSL efficiency while minimizing change of existing hardware and a DSL system including the same. .

The high-speed subscriber network is represented by ADSL using telephone copper wire, which is only insufficient for high-speed multimedia services because it can only deliver downlink of several Mbps and up to several hundred Kbps. The VD SL, which can achieve speeds of 100Mbps or more, may be an alternative, but since this can only solve the distance of 1,200 meters from the home entrance, the existing high speed subscriber network has limitations of speed and distance.

In order to solve this problem, the high-speed subscriber network is being replaced by optical fibers, but the installation of optical fibers to small and medium-sized cities or farming and fishing villages with low population density has a problem in that it is not economical because the cost is too high.

The present invention is to overcome the above-mentioned conventional problems, the problem to be solved by the present invention is installed between the commercially available Ethernet switch chip and PHY (physical layer) chip, EFM bonding technology without changing the existing commercialized chip The present invention is to provide an EFM bonding device and a DSL system including the same, which can be implemented in a central office (CO) device and a customer premises equipment (CPE) device to improve the speed or service distance of an existing VDSL / ADSL.

According to an exemplary embodiment of the present invention, the EFM bonding execution input unit for restoring the Ethernet frame from the input signal to perform the fragment of the Ethernet frame, and output the fragmented Ethernet frame; An output DSL port for storing a fragmented Ethernet frame received from the EFM bonding execution input unit and converting and outputting the fragmented Ethernet frame; An input DSL port for converting a signal received through a copper telephone line into a fragmented Ethernet frame and outputting a fragmented Ethernet frame; And an EFM bonding execution output unit for reassembling the fragmented Ethernet frame received from the input DSL port, restoring the original Ethernet frame, and converting and outputting the restored Ethernet frame.

The EFM bonding execution input unit may include an Ethernet frame extracting unit configured to recover an Ethernet frame from a signal input from an Ethernet switch chip or an application; An uplink input buffer for storing the Ethernet frame received from the Ethernet frame extracting unit; An uplink input buffer manager to control the uplink input buffer; A fragment execution unit that performs fragments of Ethernet frames stored in the uplink input buffer according to a fragmentation control signal received from a control device; And a scheduler that controls which output DSL port to send the fragmented Ethernet frame to.

The uplink input buffer management unit transmits whether the Ethernet frame is stored in the uplink input buffer and the size information of the stored Ethernet frame to the fragment execution unit.

The fragment execution unit reads the Ethernet frame according to the data size set according to the fragmentation control signal, and adds a fragmentation header before the fragmented Ethernet data.

The fragmentation header includes a sequence number, a start of packet (SOP) and an end of packet (EOP).

The output DSL port includes a DSL output buffer for storing a fragmented Ethernet frame received from the scheduler; A DSL output buffer manager to control the DSL output buffer, detect a storage state of an Ethernet frame fragmented in the DSL output buffer, and transmit a result to the scheduler; And a signal converter for converting and outputting a fragmented Ethernet frame applied from the DSL output buffer.

The input DSL port includes a fragment recovery unit for converting a signal received through the copper telephone line into a fragmented Ethernet frame; A DSL input buffer for storing a fragmented Ethernet frame received from the fragment recovery unit; And a DSL input buffer manager for controlling the DSL input buffer.

The DSL input buffer manager extracts sequence number, SOP, and EOP information from the fragmentation header of the fragmented Ethernet frame stored in the DSL input buffer, and transfers the extracted information to the EFM bonding execution output unit.

When the DSL input buffer manager receives the transmission request signal of the fragmented Ethernet frame from the EFM bonding execution output unit, the DSL input buffer manager transmits the fragmented Ethernet frame to the EFM bonding execution output unit.

The EFM bonding execution output unit may include: a fragment reassembly unit configured to reassemble a fragmented Ethernet frame received from the input DSL port to restore an original Ethernet frame; An uplink output buffer for storing the Ethernet frame received from the fragment reassembly unit; An uplink output buffer manager for controlling the uplink output buffer; And a signal converter configured to convert and output a signal of an Ethernet frame stored in the uplink output buffer.

The fragment assembler compares the sequence number to be received at this point and the sequence number received from the plurality of DSL input buffer managers, SOP, and EOP information to obtain an Ethernet frame fragmented in a DSL input buffer. And transmits the transmission request signal of the fragmented Ethernet frame to the DSL input buffer management unit of the corresponding input DSL port.

According to another aspect of the invention, the CO device for performing data communication using the optical fiber; And a CPE connected to the CO apparatus by a copper telephone line and transmitting and receiving data using the copper telephone line, wherein the CO apparatus and the CPE each include an EFM bonding apparatus according to the present invention.

According to the present invention, it is possible to maximize the service effect of the DSL system by using the existing telephone copper wire without additional infrastructure investment.

In addition, EFM bonding technology can be implemented in a central office (CO) device and a customer premises equipment (CPE) device without changing a commercially available chip, thereby improving the speed or service distance of the existing VDSL / ADSL.

1 is a conceptual diagram of a DSL system using EFM.
2 is a functional block diagram of a CO device of a DSL system according to an embodiment of the present invention, Figure 3 is a CPE functional block diagram of a DSL system according to the present invention.
4 is a schematic functional block diagram of an EFM bonding apparatus according to an embodiment of the present invention.
FIG. 5 is a functional block diagram of an EFM bonding execution input unit of the EFM bonding apparatus shown in FIG. 4.
FIG. 6 is a functional block diagram of an output DSL port of the EFM bonding apparatus shown in FIG. 4.
FIG. 7 is a functional block diagram of an input DSL port of the EFM bonding apparatus shown in FIG. 4.
8 is a functional block diagram of an EFM bonding execution output unit of the EFM bonding apparatus shown in FIG. 4.
9 is a schematic diagram of an Ethernet frame data structure.
10 is a flowchart illustrating a data transmission process from a CO device of a DSL system to a CPE according to the present invention, and FIG. 11 is a flowchart illustrating an Ethernet frame recovery process in a CPE of a DSL system according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

1 is a conceptual diagram of a DSL system using EFM.

Referring to FIG. 1, the copper loop bonding technology is an IEEE802.3ah standard (i.e., an Ethernet in the First Mile (EMF) is a fiber optic device for a central office (CO) device such as a router or an Ethernet switch). It is a technology that transmits data using a telephone line (copper loop) that is already installed from the telephone company to the customer premises equipment (CPE).

A router is a dedicated network element that receives packets and forwards them to their destination. DSLAM refers to a digital subscriber line access multiplexer used to separate signals from multiple local xDSL loops into analog voice signals for a public switched telephone network (PSTN) and data signals for a core network.

The xDSL detailed below refers to any version of a digital subscriber line (DSL) that sends and receives packets between an end-user's modem and an access node connected to the core network, for example, a digital subscriber line access multiplexer (DSLAM). DSL versions include asynchronous DSL, synchronous DSL rate DSL, hybrid DSL, and very high bit rate DSL.

2 is a functional block diagram of a CO device of a DSL system according to an embodiment of the present invention, Figure 3 is a CPE functional block diagram of a DSL system according to the present invention.

Referring to FIG. 2, the CO apparatus 500 includes an uplink data transceiver 100, an Ethernet switch chip 200, an EFM bonding apparatus 300, and an xDSL line data transceiver 400. The CO apparatus 500 is a device that manages subscribers and subscriber lines of a predetermined area in a telephone network. The subscriber lines are terminated, and interconnection between subscribers and other telephone stations such as relay stations, intercity stations, and international stations are made.

The uplink data transmission / reception unit 100 transmits and receives data through an optical fiber, and in the present embodiment, a giga bit up link card is used.

The Ethernet switch chip 200 is installed at the rear end of the uplink data transmission / reception unit 100 and determines the address address (MAC address) of the receiving terminal stored in the data frame and transmits data only to the port to which the terminal is connected. Perform the function.

The EFM bonding device 300 is installed at the rear end of the Ethernet switch chip 200. The EFM bonding apparatus 300 extracts an Ethernet frame during data downlink, fragments the Ethernet frame, and converts the fragmented Ethernet frame into a signal and outputs the signal. Also, after extracting the fragmented Ethernet frame during data uplink, the fragment is reassembled to restore the original Ethernet frame, and the converted original Ethernet frame is signal converted and output.

The xDSL line data transmission / reception unit 400 is installed at the rear end of the EFM bonding apparatus 300 and transmits an output signal applied from the EFM bonding apparatus 300 to the CPE 1000 through the plurality of xDSL lines 50. Then, the signal transmitted from the CPE 1000 is applied to the EFM bonding apparatus 300 through the plurality of xDSL lines 50. In the present embodiment, the xDSL line data transmission / reception unit 400 uses an xDSL line card, and the xDSL line uses a conventional copper telephone line.

Referring to FIG. 3, the CPE 100 includes an xDSL line data transceiver 600, an EFM bonding apparatus 700, a MAC 800, and an application 900.

The CPE 100, that is, the customer premises device, is installed in the customer's premises so that user devices and devices such as telephones, various data terminal devices (DTEs), computers, multiplexers (MUXs), and private exchanges (PBXs) may be used. It is a device that can be used by connecting to a transmission path.

The xDSL line data transceiver 600 applies a signal transmitted from the CO apparatus 500 through the plurality of xDSL lines 50 to the EFM bonding apparatus 700. Then, the output signal applied from the EFM bonding apparatus 700 is transmitted to the CO apparatus 500 through the plurality of xDSL lines 50. Since the EFM bonding apparatus 700 has the same function as the EFM bonding apparatus 300 in the CO apparatus 500, detailed description thereof will be omitted. The signal output from the EFM bonding apparatus 700 is transmitted to the application 900 via the MAC 800.

4 is a schematic functional block diagram of an EFM bonding apparatus according to an embodiment of the present invention.

Referring to FIG. 4, the EFM bonding apparatus 300 includes an EFM bonding execution input unit 310, an output DSL port 320, an input DSL port 330, and an EFM bonding execution output unit 340. Since the EFM bonding apparatus 700 of the CPE 1000 is also the same in structure and function as the EFM bonding apparatus 300 of the CO apparatus 500, the description thereof will be omitted.

The EFM bonding execution input unit 310 restores the Ethernet frame from the MII signal received from the Ethernet switch chip 200, performs the fragmentation of the Ethernet frame, and sends the fragmented Ethernet frame to the output DSL port 320. send.

The output DSL port 320 stores the fragmented Ethernet frame received from the EFM bonding execution input unit 310, converts the fragmented Ethernet frame into a MII signal, and then xDSL line data transmission / reception unit 400. To send.

The input DSL port 330 converts the MII signal received from the xDSL line data transceiver 400 into a fragmented Ethernet frame and transmits the fragmented Ethernet frame to the EFM bonding execution output unit 340.

The EFM bonding execution output unit 340 reassembles the fragmented Ethernet frame received from the input DSL port 330 to restore the original Ethernet frame, converts the restored Ethernet frame into a MII signal, and then switches the Ethernet switch chip. Send to (200).

FIG. 5 is a functional block diagram of an EFM bonding execution input unit of the EFM bonding apparatus shown in FIG. 4.

Referring to FIG. 5, the EFM bonding execution input unit 310 may include an Ethernet frame extracting unit 311, an uplink input buffer manager 312, an uplink input buffer 313, a fragment execution unit 314, and a scheduler ( 315).

The Ethernet frame extracting unit 311 restores the Ethernet frame from the MII signal transmitted from the Ethernet switch chip 200 to the MII (Media Independent Interface) standard, and transmits the Ethernet frame to the uplink input buffer manager 312.

The uplink input buffer 313 stores the Ethernet frame received from the uplink input buffer manager 312. In this embodiment, the uplink input buffer 313 is designed to store at least two Ethernet frames.

The uplink input buffer management unit 312 controls the uplink input buffer 313, and whether the Ethernet frame is stored in the uplink input buffer 313 and the size information of the stored Ethernet frame fragment execution unit 314 To pass).

The fragment execution unit 314 receives a fragmentation control signal for how many bytes the Ethernet frame is fragmented by the controller, i.e., the CPU, and according to the received fragmentation control signal, an uplink input buffer ( Read an Ethernet frame. Then, a 2-byte fragmentation header is added before the fragmented Ethernet data.

The scheduler 315 determines which DSL output port the Ethernet frame is sent to according to the control signal transmitted from the DSL output buffer manager 321 below, and is fragmented to the corresponding output DSL port 320. Pass an Ethernet frame.

FIG. 6 is a functional block diagram of an output DSL port of the EFM bonding apparatus shown in FIG. 4.

Referring to FIG. 6, the output DSL port 320 includes a DSL output buffer manager 321, a DSL output buffer 322, and an MII converter 323.

The fragmented Ethernet frame received from the scheduler 315 is transmitted to the DSL output buffer 322 via the DSL output buffer manager 321. The DSL output buffer 322 stores at least two fragmented Ethernet frames, and transmits the stored fragmented Ethernet frames to the MMI converter 323.

The DSL output buffer manager 321 controls the DSL output buffer 322, detects how much Ethernet frames fragmented are stored in the DSL output buffer 322, and transmits the result to the scheduler 315. .

The MII converter 323 converts the fragmented Ethernet frame applied from the DSL output buffer 322 into an MII signal and transmits the signal to the xDSL line data transceiver 400.

FIG. 7 is a functional block diagram of an input DSL port of the EFM bonding apparatus shown in FIG. 4.

Referring to FIG. 7, the input DSL port 330 includes a fragment recovery unit 331, a DSL input buffer manager 332, and a DSL input buffer 333.

The fragment recovery unit 331 converts the MII signal received from the xDSL line data transceiver 400 into a fragmented Ethernet frame. The DSL input buffer 333 stores the fragmented Ethernet frame.

The DSL input buffer management unit 332 controls the DSL input buffer 333, the sequence number and the start of packet (SOP), in the fragmentation header of the fragmented Ethernet frame stored in the DSL input buffer 333, EOP (End Of Packet) information is extracted and the extracted information is transferred to the fragment reassembly unit 341 of the EFM bonding execution output unit 340. In addition, when the fragment reassembly unit 341 receives the transmission request signal of the fragmented Ethernet frame, the fragmented Ethernet frame is transmitted to the fragment reassembly unit 341.

8 is a functional block diagram of an EFM bonding execution output unit of the EFM bonding apparatus shown in FIG. 4.

Referring to FIG. 8, the EFM bonding execution output unit 340 includes a fragment reassembly unit 341, an uplink output buffer manager 342, an uplink output buffer 343, and an MII converter 344. do.

The fragment reassembly 341 receives the fragmented Ethernet frame from the input DSL port 330, reassembles, and restores the original inner frame.

The fragment assembler 341 compares the sequence number to be received at the present time with the sequence number received from the plurality of DSL input buffer managers 332, SOP, and EOP information. Determines whether to import the fragmented Ethernet frame, and transmits a transmission request signal of the fragmented Ethernet frame to the DSL input buffer management unit 332 of the corresponding input DSL port.

If the fragment with SOP information is the first part of the Ethernet frame and continues to assemble the fragments in sequence number order, when receiving the fragment with EOP information, the assembly of the Ethernet frame is stopped and the original Ethernet frame is restored. do.

The uplink output buffer 343 stores the assembled Ethernet frame, and is designed to store at least two Ethernet frames in this embodiment.

The uplink output buffer manager 342 controls the uplink output buffer 343.

The MII converter 344 converts the Ethernet frame stored in the uplink output buffer 343 into an MII signal and transmits the converted MII signal to the Ethernet switch chip 200.

9 is a schematic diagram of an Ethernet frame data structure. 9 shows the structure of a fragmented Ethernet frame. A fragmentation header is inserted before the fragment data, and the fragmentation header is composed of a sequence number (14 bits), an SOP signal (1 bit), and an EOP signal (1 bit).

10 is a flowchart illustrating a data transmission process from a CO device of a DSL system to a CPE according to the present invention, and FIG. 11 is a flowchart illustrating an Ethernet frame recovery process in a CPE of a DSL system according to the present invention. 10 and 11 illustrate only a process of downlinking data from a CO device to a CPE, but a process of uplinking data from a CPE to a CO device is in reverse order, and thus description thereof will be omitted.

Referring to FIG. 10, an Ethernet frame is recovered from an MII signal received from the Ethernet switch chip 200 (S10). The Ethernet frame is stored in the uplink input buffer through the uplink input buffer manager (S20).

The Ethernet frame fragment is performed (S30). That is, the Ethernet frame is read from the uplink input buffer according to the fragmentation control signal, and a fragmentation header is added.

Thereafter, the fragmented Ethernet frame is transmitted to the output DSL port, and the transmitted fragmented Ethernet frame is stored in the DSL output buffer (S40).

The fragmented Ethernet frame is converted into an MII signal (S50). Then, the MII signal transmits data to the CPE in a multipath through a plurality of xDSL lines, that is, copper telephone lines (S60).

Referring to FIG. 11, the MII signal received through a copper telephone line is converted into a fragmented Ethernet frame (S110). The fragmented Ethernet frame is stored in the DSL input buffer (S120).

The fragment header information of the fragmented Ethernet frame is received from the DSL input buffer manager (S130). It is determined whether the sequence number to be received at this point and the sequence number received from the DSL input buffer manager are identical (S140).

As a result of determination, if both sequence numbers match, a request for transmission of the fragmented Ethernet frame is transmitted to the DSL input buffer management unit that transmits the sequence number, and the fragmented Ethernet frame is received to reassemble the fragment. Restore the original Ethernet frame by performing (S150).

The restored Ethernet frame is stored in the uplink output buffer (S160). Then, after converting to the MII signal, the data is transmitted in the converted signal (S170).

On the other hand, if the sequence numbers do not match, it is determined whether the preset waiting time is exceeded (S180). As a result of the determination, if the waiting time has not been exceeded, the process returns to step S130, and if the waiting time is exceeded, the data reception error is processed (S190).

What has been described above is only an exemplary embodiment of an EFM bonding apparatus and a DSL system including the same according to the present invention, and the present invention is not limited to the above-described embodiment, as claimed in the following claims, Without departing from the gist of the invention, anyone of ordinary skill in the art to which the present invention will have the technical spirit of the present invention to the extent that various modifications can be made.

310: EFM bonding execution input unit
320: output DSL port
330: input DSL port
340: EFM bonding execution output unit

Claims (12)

In the EFM bonding apparatus,
An EFM bonding execution input unit for restoring the Ethernet frame from the input signal, performing fragmentation of the Ethernet frame, and outputting the fragmented Ethernet frame;
An output DSL port for storing a fragmented Ethernet frame received from the EFM bonding execution input unit and converting and outputting the fragmented Ethernet frame;
An input DSL port for converting a signal received through a copper telephone line into a fragmented Ethernet frame and outputting a fragmented Ethernet frame; And
And an EFM bonding execution output unit for reassembling the fragmented Ethernet frame received from the input DSL port, restoring the original Ethernet frame, and converting and outputting the restored Ethernet frame.
The method of claim 1,
The EFM bonding execution input unit,
An Ethernet frame extracting unit for restoring an Ethernet frame from a signal input from an Ethernet switch chip or an application;
An uplink input buffer for storing the Ethernet frame received from the Ethernet frame extracting unit;
An uplink input buffer manager to control the uplink input buffer;
A fragment execution unit that performs fragments of Ethernet frames stored in the uplink input buffer according to a fragmentation control signal received from a control device; And
And a scheduler for controlling which output DSL port to send a fragmented Ethernet frame to.
The method of claim 2,
And the uplink input buffer management unit transmits information on whether the Ethernet frame is stored in the uplink input buffer and the size information of the stored Ethernet frame to the fragment execution unit.
The method of claim 2,
And the fragment execution unit reads the Ethernet frame according to the data size set according to the fragmentation control signal, and adds a fragmentation header before the fragmented Ethernet data.
The method of claim 4, wherein
The fragmentation header EFM bonding apparatus comprising a sequence number, Start Of Packet (SOP) and End Of Packet (EOP).
The method of claim 1,
The output DSL port,
A DSL output buffer for storing a fragmented Ethernet frame received from the scheduler;
A DSL output buffer manager to control the DSL output buffer, detect a storage state of an Ethernet frame fragmented in the DSL output buffer, and transmit a result to the scheduler; And
And a signal converter for converting and outputting a fragmented Ethernet frame applied from the DSL output buffer.
The method of claim 1,
The input DSL port is
A fragment recovery unit for converting a signal received through the copper telephone line into a fragmented Ethernet frame;
A DSL input buffer for storing a fragmented Ethernet frame received from the fragment recovery unit; And
EDM bonding apparatus comprising a DSL input buffer management unit for controlling the DSL input buffer.
The method of claim 7, wherein
The DSL input buffer manager extracts sequence number, SOP, and EOP information from the fragmentation header of the fragmented Ethernet frame stored in the DSL input buffer, and transfers the extracted information to the EFM bonding execution output unit. EFM bonding device.
The method of claim 8,
And the DSL input buffer management unit transmits the fragmented Ethernet frame to the EFM bonding execution output unit when receiving the transmission request signal of the fragmented Ethernet frame from the EFM bonding execution output unit.
The method of claim 1,
The EFM bonding execution output unit,
A fragment reassembly unit for reassembling the fragmented Ethernet frame received from the input DSL port to restore the original Ethernet frame;
An uplink output buffer for storing the Ethernet frame received from the fragment reassembly unit;
An uplink output buffer manager for controlling the uplink output buffer; And
EFM bonding apparatus comprising a signal converter for converting and outputting the signal of the Ethernet frame stored in the uplink output buffer.
The method of claim 10,
The fragment assembler compares the sequence number to be received at this point and the sequence number received from the plurality of DSL input buffer managers, SOP, and EOP information to obtain an Ethernet frame fragmented in a DSL input buffer. And the transmission request signal of the fragmented Ethernet frame to the DSL input buffer management unit of the corresponding input DSL port.
In a DSL system,
CO apparatus for performing data communication using the optical fiber; And
A CPE connected to the CO apparatus by a copper telephone line and transmitting and receiving data using the copper telephone line;
12. The DSL system according to claim 1, wherein the CO device and the CPE each comprise an EFM bonding device according to any one of claims 1-11.

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