KR20020047453A - TRANSCEIVER APPARATUS FOR 2.5Gbps OPTICAL TRANSMISSION - Google Patents

Abstract

PURPOSE: A transceiver device for 2.5Gbps optical transmission is provided to easily and variously embody interfaces with other modules by extracting an STM-16(Synchronous Transport Module level 16) overhead and an STM-16 frame, processing the STM-16 overhead and the STM-16 frame by an STM-1 unit, and interfacing the STM-16 overhead and the STM-16 frame with the outside. CONSTITUTION: An STM-16 optical receiver(111) receives an STM-16 optical signal through an external optical line and converts the received STM-16 optical signal into an STM-16 electric signal. A CRU(Clock Recovery Unit)(120) extracts a clock signal in which a frequency and a phase are identical to an STM-16 signal from the STM-16 electric signal. A demultiplexer(131) demultiplexes the STM-16 electric signal received from the STM-16 optical receiver(111) for dividing the STM-16 electric signal into 155Mbps signal with 16 bits. An STM-16 transport terminator(140) performs a frame arrangement of the 155Mbps signal with 16 bits received from the demultiplexer(131) using the clock signal extracted from the CRU(120), extracts an overhead, converts the 155Mbps signal with 16 bits into an STM-1 signal with 16 channels, and transmits the STM-1 signal with 16 channels to an external interface. The STM-16 transport terminator(140) receives the STM-1 signal with 16 channels, converts the received STM-1 signal with 16 channels into the 155Mbps signal with 16 bits, and inserts an overhead into the 155Mbps signal with 16 bits. A multiplexer(133) receives the 155Mbps signal with 16 bits from the STM-16 transport terminator(140) and multiplexes the received 155Mbps signal with 16 bits into an STM-16 signal according to the clock signal received from the CRU(120). An STM-16 optical transmitter(113) receives the STM-16 electric signal from the multiplexer(133), converts the received STM-16 electric signal into an optical signal, and transmits the optical signal to the outside through the optical line.

Description

Transceiver device for 2.5Hz optical transmission {TRANSCEIVER APPARATUS FOR 2.5Gbps OPTICAL TRANSMISSION}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a 2.5 Gbps optical transmission transceiver. It is about.

As is well known, Synchronous Optical Network (SONET) / SDH is a physical layer standard that is applied to the optical cable section of virtually all long-distance telephone networks around the world.The goal of SONET / SDH is to relate to the wavelength, timing, and framing that different operators can work with. By defining a common signaling standard, we will integrate digital systems in the Americas, Europe, and Asia, and provide a means to efficiently carry digital signals on optical cables with Gigabit or higher transmission rates.

Because SONET / SDH is designed as a synchronous system, the entire bandwidth is used as one large channel that contains multiple time slots allocated to various subchannels, and the carrier frame is constantly in 125ms intervals regardless of user data. Is sent.

The prior art transceiver device for 2.5 Gbps optical transmission incorporates a 2.5 Gbps optical transmitter, a 2.5 Gbps optical receiver, a clock synthesizer and a clock recoverer.

This 2.5 Gbps optical transceiver device supports SDH all-optical interface between the SDH optical physical layer and the electrical section layer, and multiplexes 16 bits of 155 Mbps signal into 2.5 Gbps serial data through 2.5 Gbps optical transmitter and 2.5 Gbps optical receiver. Conversely, demultiplexing is performed.

However, in the case of 2.5Gbps optical transmission, a separate STM-16 overhead processor must be configured as an external interface of 155Mbps to extract the STM-16 overhead and reconfigure the STM-1 frame configuration.

As such, since the 2.5 Gbps optical transmission module and the STM-16 overhead processor module are separately separated, there is a problem in that the interface between the modules is difficult and inconvenient to implement various interfaces.

The present invention has been proposed to solve such a conventional problem, and its purpose is to extract the STM-16 (Synchronous Transport Module level 16; 2.5 Gbps) overhead and the STM-16 frame and then process the STM-1 unit. By providing a 2.5Gbps optical transmission transceiver device that interfaces externally, it is possible to more easily implement a variety of interfaces with other modules.

In accordance with an aspect of the present invention, there is provided a 2.5Gbps optical transceiver apparatus comprising: an STM-16 optical receiver which receives an STM-16 optical signal through an external optical path and converts the STM-16 optical signal into an STM-16 electrical signal; A CRU extracting and outputting a clock signal having the same frequency and phase as the STM-16 signal from the STM-16 electrical signal; A demultiplexer for demultiplexing the STM-16 electrical signal received from the STM-16 optical receiver and separating the STM-16 electrical signal into a 16-bit 155Mbps signal; The 16-bit 155 Mbps signal received from the demultiplexer is frame-aligned, the overhead is extracted, and the 16-channel STM-1 signal is converted into a 16-channel STM-1 signal using the clock signal extracted from the CRU and transmitted to the external interface. An STM-16 transport terminator that receives an STM-1 signal of a channel, converts the signal into a 16-bit 155Mbps signal, and inserts an overhead to output the STM-1 signal; A multiplexer for receiving the 16-bit 155 Mbps signal from the STM-16 transport terminator and multiplexing the STM-16 signal according to a clock signal received from the CRU; And a STM-16 optical transmitter for receiving an STM-16 electrical signal from the multiplexer, converting the STM-16 electrical signal into an optical signal, and then transmitting the optical signal to the outside through an optical path.

1 is a block diagram of a transceiver device for 2.5Gbps optical transmission according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100 transceiver unit 111 STM-16 optical receiver

113: STM-16 optical transmitter 120: CRU (Clock Recovery Unit)

131: demultiplexer 133: multiplexer

140: STM-16 Transport Terminator

There may be a plurality of embodiments of the present invention, hereinafter with reference to the accompanying drawings will be described in detail a preferred embodiment. Through this embodiment, it is possible to better understand the objects, features and advantages of the present invention.

1 is a block diagram of a transceiver device for 2.5Gbps optical transmission according to the present invention.

As shown therein, the transceiver device 100 of the present invention includes an STM-16 optical receiver 111, a CRU (Clock Recovery Unit) 120, a demultiplexer 131, and an STM-16 transport terminator. 140, a multiplexer 133, and an STM-16 optical transmitter 113.

The STM-16 optical receiver 111 receives the STM-16 optical signal according to the recommendation of the International Telecommunication Union (ITU-T) through the optical path from the external optical transmission device and converts it into an STM-16 electrical signal before the CRU 120 To send).

The CRU 120 extracts a clock signal having the same frequency and phase as the STM-16 signal and transmits the same to the demultiplexer 131 to synchronize the STM-16 signal.

The demultiplexer 131 simply demultiplexes the STM-16 signal received from the STM-16 optical receiver 111 into 1:16, separates it into a 16-bit 155Mbps signal, and transmits the same to the STM-16 transport terminator 140. .

The STM-16 transport terminator 140 uses the received synchronous clock signal received from the demultiplexer 131 to frame-align the 16-bit 155 Mbps signal received from the demultiplexer 131 and descrambles it for overhead processing. )do. The overhead is extracted from the demixed signal and converted into 16 channels of STM-1 signal for transmission to the external interface.

In addition, the STM-16 transport terminator 140 receives an STM-1 signal of 16 channels together with a frame signal and a clock signal from an external interface, and converts the STM-16 transport terminator 140 into a 16-bit 155Mbps signal. At this time, the STM-16 transport terminator 140 inserts the overhead received from the external interface. Thereafter, the STM-16 transport terminator 140 transmits a 16-bit 155Mbps signal to the multiplexer 133.

The multiplexer 133 receives a 16-bit 155 Mbps signal from the STM-16 transport terminator 140 and 16: 1 multiplexes the STM-16 signal according to a clock signal received from the CRU 120 to perform an STM-16 optical transmitter ( 113).

The STM-16 optical transmitter 113 receives an STM-16 electrical signal from the multiplexer 133, converts the STM-16 electrical signal into an optical signal, and transmits the optical signal to an external optical transmission device through an optical path.

The operation of the 2.5Gbps optical transmission transceiver device according to the present invention configured as described above is as follows.

First, the STM-16 optical receiver 111 receives an STM-16 optical signal from an external optical transmission device in accordance with the recommendation of the International Telecommunication Union (ITU-T) via an optical path. The received signal is converted into an STM-16 electrical signal and output to the CRU 120.

At this time, the CRU 120 extracts a clock signal having the same frequency and phase as the STM-16 electrical signal and outputs the same to the demultiplexer 131 with the STM-16 electrical signal for signal synchronization.

The demultiplexer 131 receives the STM-16 data and the clock signal from the STM-16 optical receiver 111, respectively, and then converts the STM-16 data into a 16-bit 155 Mbps signal using the received clock to transmit the STM-16 transport. Output to the terminator 140.

The STM-16 transport terminator 140 receives a 16-bit 155Mbps signal and a receive synchronous clock signal received from the demultiplexer 131. The 16-bit 155Mbps signal is frame aligned after being converted to 16 channels of STM-1 signals in accordance with the received synchronous clock signal. The STM-1 signal is demixed for overhead processing. Interval summation lines and communication channel data extracted from the overhead of the demixed signal are transmitted to the external interface.

On the other hand, the 16-channel STM-1 signal received from the external interface to the STM-16 transport terminator 140 is purified to the received synchronous clock signal input from the CRU 120 through the multiplexer 133 and is a 16-bit 155Mbps signal. Is converted to. At this time, the interval matching line and the communication channel data received from the external interface are inserted in the overhead of the 16-bit 155Mbps signal, and then the 16-bit 155Mbps signal is output to the multiplexer 4.

The multiplexer 133 receives a 16-bit 155 Mbps signal from the STM-16 transport terminator 140. The received 16-bit 155Mbps signal is converted into an STM-16 electrical signal according to the Recommendation of the International Telecommunication Union (ITU-T) by a 16: 1 multiplexing process and output to the STM-16 optical transmitter 113. In this case, the multiplexer 133 receives a synchronous clock signal supplied by the CRU 120 as a synchronous clock signal for 16: 1 multiplexing.

STM-16 optical transmitter 113 receives STM-16 electrical signals from multiplexer 133. The received signal is converted into an STM-16 optical signal and then transmitted to an external optical transmission device through an optical path.

As described above, the 2.5Gbps optical transceiver apparatus of the present invention extracts the STM-16 overhead and the STM-16 frame from the STM-16 electrical signal in the internal STM-16 transport terminator and processes the STM-1 unit. External interface.

Therefore, the interface with other modules can be implemented very easily and variously.

Claims (1)

An STM-16 optical receiver which receives an STM-16 optical signal through an external optical path, converts the STM-16 optical signal into an STM-16 electrical signal, and outputs the STM-16 optical signal; A CRU extracting and outputting a clock signal having the same frequency and phase as the STM-16 signal from the STM-16 electrical signal; A demultiplexer for demultiplexing the STM-16 electrical signal received from the STM-16 optical receiver and separating the STM-16 electrical signal into a 16-bit 155Mbps signal; The 16-bit 155 Mbps signal received from the demultiplexer is frame-aligned, the overhead is extracted, and the 16-channel STM-1 signal is converted into a 16-channel STM-1 signal using the clock signal extracted from the CRU and transmitted to the external interface. An STM-16 transport terminator that receives an STM-1 signal of a channel, converts the signal into a 16-bit 155Mbps signal, and inserts an overhead to output the STM-1 signal; A multiplexer for receiving the 16-bit 155 Mbps signal from the STM-16 transport terminator and multiplexing the STM-16 signal according to a clock signal received from the CRU; And a STM-16 optical transmitter for receiving an STM-16 electrical signal from the multiplexer, converting the STM-16 electrical signal into an optical signal, and transmitting the optical signal to the outside through an optical path.