KR100477179B1 - Apparatus of Optical Transit Transmission - Google Patents

Abstract

The present invention relates to an optical relay transmission apparatus which multiplexes a DS1E signal and an Ethernet signal into one optical signal and transmits and receives a single optical transmission line.

In the conventional optical relay transmission apparatus, the DS1E signal and the Ethernet signal are separately transmitted by using two optical transmission paths, which is expensive using two optical transmission paths, and the DS1E signal is encapsulated in an IP packet. In the transmission method, the quality of the line signal is degraded due to the delay due to the IP packet conversion, and the transmission method using the ATM method is complicated because it is encapsulated in the form of an ATM cell. .

According to the present invention, by using a frame format capable of accommodating Fast Ethernet signals and DS1E signals, different types of signals, packet type Fast Ethernet signals, and line type DS1E signals are accommodated in one frame to transmit one optical signal. The ability to send and receive over the line simplifies the circuit, reduces cost, and eases maintenance. In addition, since TDM multiplexing is performed in a line-shaped frame format including timing synchronization information, the original clock source is easier to transmit than when encapsulated in an Ethernet packet, and transmission performance and quality performance of a signal are improved.

Description

Optical relay transmission device {Apparatus of Optical Transit Transmission}

The present invention relates to an optical relay transmission apparatus, and more particularly, to an optical relay transmission apparatus that multiplexes a DS1E signal and an Ethernet signal into one optical signal and transmits and receives a single optical transmission line.

A method for converting a DS1E signal in a circuit form and an Ethernet signal in a packet form into an optical signal and transmitting the optical signal to a central office, etc. In the optical relay transmission device, the DS1E is conventionally used by using two optical transmission paths. There are a method of separately transmitting a signal and an Ethernet signal, a method of encapsulating a DS1E signal into an IP packet, and a method of transmitting using an ATM method.

As illustrated in FIG. 1, the apparatus for transmitting an optical relay according to the first method transmits a subscriber signal between an exchange or a station, which is located in a central office and is transmitted through a DS1E multiplexer 10 of a remote terminal (RT). DS1E (2.048 Mbps), the European primary military speed, is transmitted through the DS1E (20), which serves to deliver the device, and the DS1E multiplexer (10) connected to the subscriber, which is located at the subscriber side where a large-capacity line is needed. 100 Mbps Fast Ethernet through Fast Ethernet 30 and Router 40, and an optical transmission line that multiplexes synchronous multiplexed STM-1 (Synchronous Transport Module-1) signals and transmits them as optical signals of 155.520 Mbps Each requires an optical transmission line for transmitting an optical signal.

Accordingly, the cost of using two optical lines is expensive, and both a circuit for multiplexing the DS1E signal and a circuit for multiplexing the fast Ethernet signal are required, resulting in a complicated circuit and difficult maintenance.

In the second method described above, since the DS1E signal in the form of a line is converted into an Ethernet packet and transmitted, the quality of the line signal is degraded due to the delay caused by the conversion. In addition, since the timing signal must be accurately synchronized, the line signal converts the DS1E signal into a packet and transmits the packet, thereby making it difficult to transmit the original clock source. In addition, all packet networks have difficulty in guaranteeing quality of circuit signals.

In the third method described above, as shown in FIG. 2, the DS1E signal and the Ethernet signal are encapsulated in an ATM signal through AAL (ATM Adaptation Layer), ATM, and SDH (Synchronous Digital Hierarchy), and transmitted together. There is an advantage that quality of service (QoS) can be guaranteed for the circuit, but the method is complicated because it encapsulates in ATM cell form through AAL, ATM, SDH steps, and there is a problem that all networks must be composed of ATM networks. .

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and by using a frame format capable of accommodating Fast Ethernet signals and DS1E signals, different types of signals are accommodated in one frame, thereby receiving Fast Ethernet signals and DS1E signals. An object of the present invention is to provide an optical relay transmission apparatus capable of transmitting and receiving together in one optical transmission line.

In accordance with another aspect of the present invention, there is provided an optical relay transmission apparatus comprising: a first complex multiplexer for multiplexing an Ethernet signal and a DS1E signal into one frame signal for optical transmission; And a second complex multiplexer for restoring the Ethernet signal and the DS1E signal from the frame signal received from the first complex multiplexer.

Here, the first and second complex multiplexers may include two slow multiplexers for multiplexing the DS1E signal into a frame signal in synchronization with a system clock and extracting the DS1E signal from the received frame signal; And a high speed multiplexer for multiplexing the frame signal and the Ethernet signal received from the low speed multiplexer into a frame signal, and extracting the DS1E frame signal and the Ethernet signal from the received frame signal.

The high speed multiplexer may include: an Ethernet connection unit determining whether an input Ethernet signal is valid data; A TDM converter for encapsulating the Ethernet signal received from the Ethernet connection unit into a header and a trailer to produce parallel data and outputting the same; And a memory unit configured to store data output from the TDM converter and to output the data in synchronization with a system clock.

In addition, the frame signal includes four subframes, and one subframe includes eight cells.

The cell may include an overhead bit; Ethernet TDM data; Characterized in that it comprises the DS1E multiplexed data received from each of the slow multiplexer.

Hereinafter, an optical relay transmission apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a road showing the configuration of the optical relay transmission apparatus according to the present invention, which is provided in the RT 100Mbps Fast Ethernet signal and eight DS1E (2.048Mbps) signal multiplexed by TDM (Time Division Modulation) to the central office terminal (COT) The first composite multiplexer 110 for optical transmission and the original signal, i.e., eight DS1E signals and 100 Mbps Fast Ethernet signals, are recovered from the multiplexed data provided in the COT and the first complex multiplexer 110. A second complex multiplexer 120 is provided.

Here, the second complex multiplexer 120 performs TDM multiplexing of eight DS1E signals and 100 Mbps Fast Ethernet signals to optically transmit the first complex multiplexer 110 to the first complex multiplexer 110. A function of restoring the original signal from the multiplexed data transmitted from the unit 120 may also be performed.

4 is a road showing the configuration of a complex multiplexer, each complex multiplexer comprising a first low speed multiplexer 113, a second low speed multiplexer 115, and a high speed multiplexer 117.

In this configuration, the first low speed multiplexer 113 and the second low speed multiplexer 115 multiplex four DS1E (2.048 Mbps) signals into 10 Mbps frame signals and transmit them to the high speed multiplexer 117. Stuffing is also performed to synchronize the DS1E signal to the system clock.

In addition, the first low speed multiplexer 113 and the second low speed multiplexer 115 extract a DS1E signal by extracting a frame from a 10 Mbps frame signal received from the high speed multiplexer 117, respectively, and analyze a stuffing bit to complete Restore the DS1E signal.

Meanwhile, the fast multiplexer 117 multiplexes the 10 Mbps frame signal and the 100 Mbps Fast Ethernet signal received from the first low speed multiplexer 113 and the second low speed multiplexer 115, respectively, into a 125 Mbps frame signal. It generates a maintenance signal (AIS, RDI, etc.), and generates a DCC (Data Communication Channel) for communication with the power station and transmits it as a 125Mbps optical signal.

In addition, the high speed multiplexer 117 extracts a maintenance signal and a DCC signal by extracting a frame from the received 125 Mbps signal, extracts two 10 Mbps signals, and transmits them to the corresponding low speed multiplexers 113 and 115, and 100 Mbps. Extract the Fast Ethernet signal.

As described above, in order to multiplex the 100 Mbps Fast Ethernet signal in the high speed multiplexer 117, the 100 Mbps Fast Ethernet signal must first be converted into a line-shaped signal, and the high speed multiplexer 117 converts the 100 Mbps Fast Ethernet signal into a line. It also performs the function of converting the signal into a form.

FIG. 5 is a diagram illustrating the configuration of a part for converting a 100 Mbps Fast Ethernet signal into a line-type signal provided in a high speed multiplexing unit, an Ethernet connection unit 117-1, a TDM conversion unit 117-3, and a FIFO 117-5. ) Is made.

In such a configuration, when the 100Mbps Fast Ethernet signal is input, the Ethernet connection unit 117-1 determines whether the input 100Mbps Fast Ethernet signal is valid data, and if it is valid data, the Ethernet connection unit 117-1 receives the input 100Mbps Fast Ethernet signal. Input to TDM converter 117-3.

The TDM conversion unit 117-3 encapsulates the 100Mbps Fast Ethernet signal received from the Ethernet connection unit 117-1 into a header of 1 byte and a trailer of 1 byte to make 20-bit parallel data, 117-5) to synchronize to the 125 Mbps frame system clock.

The FIFO 117-5 stores the data output from the TDM converter 117-3 and outputs the data in synchronization with the system clock.

As described above, one multiframe multiplexed by the high speed multiplexer 117 and output as a 125 Mbps optical signal includes four subframes, and one subframe includes eight cells ( 25 bytes), one cell structure from the overhead bit (OH), Ethernet TDM data (E), the first low-speed multiplexer 113, as shown in FIG. DS1E multiplexed data (10Mbps) 1 received and DS1E multiplexed data (10Mbps) 2 received from the second low-speed multiplexer 115 are provided.

7 is a diagram showing the structure of a multi-frame, one multi-frame is composed of 32 cells, the overhead bit 'Mx' is a multi-frame bit, 'Fx' is a sub-frame bit, 'A' is an Alarm Indication Signal bit, 'D' is a DCC (Data Communication) bit, 'RF' is a Remote Fail bit, 'P' is a Parity bit, 'R' is a reserved bit.

The optical relay transmission device of the present invention is not limited to the above-described embodiments, and may be modified and implemented in various ways within the scope of the technical idea of the present invention.

According to the optical relay apparatus of the present invention as described above, by using a frame format that can accommodate the Fast Ethernet signal and the DS1E signal, different types of signals, packet type Fast Ethernet signal and line type DS1E signal Is accommodated in one frame to transmit and receive on one optical transmission line.

Accordingly, there is an effect that the circuit becomes simpler, the cost is reduced, and the maintenance becomes easier than in the prior art of transmitting two different signals separately.

In addition, since TDM multiplexing is performed in a line-shaped frame format including timing synchronization information, the original clock source is easier to transmit than when encapsulated in an Ethernet packet, and transmission performance and quality performance of a signal are improved.

In addition, since the frame format is implemented using only the minimum overhead required, the logic circuit for multiplexing is simpler than that of the ATM method, and thus the cost is reduced.

1 and 2 are diagrams for explaining a method of optical transmission in the conventional optical relay transmission device.

3 is a diagram showing the configuration of an optical relay transmission device according to the present invention;

4 is a diagram illustrating a configuration of a complex multiplexing unit.

5 is a diagram showing a configuration of a high speed multiplexing unit.

6 is a diagram showing a structure of a multi-frame.

7 is a diagram showing the configuration of a cell.

*** Explanation of symbols for the main parts of the drawing ***

110. first multiplexer, 113. first slow multiplexer,

115. second slow multiplexer, 117. high speed multiplexer,

117-1. Ethernet connection, 117-3. TDM conversion unit,

117-5. FIFO, 120. Second Complex Multiplexer

Claims (7)

In the optical relay transmission device, A first complex multiplexing unit multiplexing the Ethernet signal and the DS1E signal into one frame signal and optically transmitting the same; And A second complex multiplexer reconstructing the frame signal received from the first complex multiplexer into the Ethernet signal and the DS1E signal, respectively; Including, The first complex multiplexer, A low speed multiplexer for multiplexing the DS1E signal into a first frame signal in synchronization with a system clock; And A high speed multiplexer for multiplexing the first frame signal and the Ethernet signal received from the low speed multiplexer into a second frame signal Including, The second complex multiplexer, A high speed multiplexer for receiving a second frame signal from the first complex multiplexer and extracting a first frame signal and an Ethernet signal from the second frame signal; And A low speed multiplexer which receives the first frame signal from the fast multiplexer and extracts a DS1E signal Optical relay transmission device comprising a. The method of claim 1, wherein the first complex multiplexing unit, An optical relay transmission device comprising multiplexing Ethernet signals and DS1E signals according to a time division multiplexing scheme. delete The method of claim 1, wherein each of the slow multiplexing unit, And a stuffing process to synchronize the DS1E signal to a system clock. The method of claim 1, wherein the fast multiplexer, An Ethernet connection unit determining whether the input Ethernet signal is valid data; A TDM converter for encapsulating the Ethernet signal received from the Ethernet connection unit into a header and a trailer to produce parallel data and outputting the same; And a memory unit configured to store data output from the TDM converter and to output the data in synchronization with a system clock. The method of claim 1, wherein the frame signal, An optical relay transmission apparatus comprising four subframes and one subframe includes eight cells. The method of claim 6, wherein the cell, An Overhead bit; Ethernet TDM data; And an DS1E multiplexed data transmitted from each low-speed multiplexer.