KR100608902B1 - External multiplexing apparatus of WDM optical transmission system - Google Patents

Abstract

According to the present invention, a wavelength division multiplexing (WDM) optical transmission system providing a high speed communication service is externally attached to the optical transmission system to efficiently satisfy a low-speed synchronous digital hierarchy (SDH) signal connection request. The present invention relates to an external multiplexing device capable of accommodating an external multiplexing device, wherein the external multiplexing device performs time division multiplexing (TDM) of a low-speed signal into a high-speed signal, and receives a high-speed signal in a WDM optical transmission system so that only wavelength division multiplexing By doing so, the WDM optical transmission system can efficiently accommodate low-speed client signals without having optical transponders having various interface standards.

Wavelength Division Multiplexing (WDM), Time Division Multiplexing (TDM), Optical Transmission Systems, Synchronous Digital Hierarchy (SDH), Optical Transponders

Description

External multiplexing apparatus of WDM optical transmission system for wavelength division multiplexing optical transmission system             

1 is an overall configuration diagram of a wavelength division multiplexing optical transmission system to which the present invention is applied.

2 is a block diagram of an external multiplexing apparatus according to the present invention.

3 is an external view of an external multiplexing device according to the present invention.

Explanation of symbols on the main parts of the drawings

21, 29: first and second photoelectric conversion unit 22, 30: first and second bit / frame synchronization unit

23, 24, 26, 31, 32, 34 Framer 25 Time Division Multiplexer
27, 35: first and second serial converter 28, 36: first and second optical converter
33: time division demultiplexer 37: control unit

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38: interface unit 39: power supply unit

  The present invention relates to a multiplexing apparatus of a wavelength division multiplexing (WDM) optical transmission system (hereinafter, referred to as a WDM optical transmission system), and more particularly, is independent of the WDM optical transmission system and operates independently. The present invention relates to an external multiplexing device for a wavelength division multiplexing optical transmission system capable of efficiently receiving a client signal.

The WDM optical transmission system is a high-speed communication system that transmits multiple channels simultaneously using light of different wavelengths. It uses two types of optical wavelengths, 1.3mm and 1.55mm, which have low attenuation in single-mode optical fiber. It is possible to transmit information of bit) through one optical fiber.

In such a high speed WDM optical transmission system, in order to accommodate a low speed client signal, an optical transponder having an optical transponder for connecting a low speed client signal is used to directly receive a low speed signal or add a function of time division multiplexing a low speed signal at high speed. Was used.

However, the method of using an optical transponder that directly accommodates the low-speed signal described in the former is inefficient because of the small capacity of the optical transponder, and has the disadvantage of inefficient time-division multiplexing of the low-speed signal described in the latter. When using an optical transponder with the added function, it is possible to efficiently receive a low speed signal. However, when a new low speed signal is required to be additionally accommodated, and a spare optical transponder is not available, a separate transponder can be purchased separately. There is an uneconomic problem that must be done.

The present invention has been proposed to solve the above problems, and an object thereof is not attached to the WDM optical transmission system, and operates independently, thereby providing an external multiplexing device for a WDM optical transmission system that can efficiently accommodate a low-speed client signal. It is.

In addition, another object of the present invention is to enable time-division multiplexing of low-speed client signals independently of the WDM optical transmission system, thereby providing an easy operation and maintenance (OAM) system for the WDM optical transmission system. It is to provide an external multiplexing device.

In order to achieve the above object, the present invention provides a plurality of first light / pre-conversion unit for converting a low-speed client signal into an electrical signal; A plurality of first bit / frame synchronization units for identifying a low speed SDH frame from an output signal of the first optical / pre-conversion unit; A time division multiplexer for arranging the low speed SDH frames identified by the plurality of first bit / frame synchronization units in a row and outputting the high speed SDH frames; A first serial converter converting a high speed SDH frame of the time division multiplexer into a serial signal; A first pre-conversion unit converting the output signal of the first serial conversion unit into an optical signal; A second light / electric conversion unit converting the high speed SDH optical signal into an electric signal; A second bit / frame synchronization unit for checking a high speed SDH frame from an output signal of the second optical / pre-conversion unit; A time division demultiplexer for dividing the SDH frame output from the second bit / frame synchronization unit into a plurality of low speed SDH frames; A plurality of second serial converters for converting a plurality of low-speed SDH frames output from the demultiplexer into serial signals, respectively; And an external multiplexing device for a wavelength division multiplexing optical transmission system including a plurality of second pre- / optical converters for converting and outputting serial signals output from the plurality of second serial converters into optical signals.

In addition, the external multiplexing apparatus according to the present invention is provided between the first bit / frame synchronization unit and the time division multiplexer to perform error detection and restoration processing in a low speed SDH frame output from the first bit / frame synchronization unit. A plurality of first framers; And a second framer disposed between the second bit / frame synchronization unit and the time division type demultiplexer to perform error detection and restoration on a high speed SDH frame output from the second bit / frame synchronization unit. A transparent operation mode in which an output of the first and second bits / frame synchronization unit is directly transmitted to a time division multiplexer and a demultiplexer, and a time division scheme of an output of the first and second bits / frame synchronization unit through a first and second framer. It is possible to selectively perform the relay operation mode to be delivered to the multiplexer and demultiplexer.

In addition, the external multiplexing apparatus according to the present invention comprises: a plurality of third framers which receive a low-speed SDH frame from the first framer and perform SDH overhead processing; A fourth framer that receives the high speed SDH frame from the second framer and performs SDH overhead processing; A fifth framer performing overhead processing on an output signal of the time division multiplexer; And a plurality of sixth frames for performing overhead processing on the output signals from the time division demultiplexer, wherein the first and second bits / frame synchronizations are time division multiplexers and demultiplexers. Transparent operation mode that connects signals in the order of serial conversion unit and delivers SDH frame as it is, first and second bit / frame synchronization unit, first and second framer, time division multiplexer, demultiplexer, and first and second serial conversion. Repeater operation mode for relaying client transmission / reception signals by connecting signals in order, first and second bit / frame synchronization unit, first and second framers, third and fourth framers, time division multiplexer, and demultiplexer. 5th, 6th framer → 1st, 2nd serial conversion section to connect the signal to selectively operate one of the multiplexer operation mode to perform the multiplexing function for the client transmission and reception signal Can.

In addition, the external multiplexing device according to the present invention WDM optical transmission system and the interface unit for exchanging control signals for operation / maintenance / repair; A control unit which transmits and receives a control signal through the interface unit and controls operations of the respective means; And a power supply unit supplying power required for the operation of each means, so that the power supply unit may operate independently of the WDM optical transmission system.

In addition, the external multiplexing apparatus according to the present invention transmits operation maintenance information such as device status and signal status through a separate line besides the WDM optical transmission system and the signal line in the transparent operation mode, and the repeater operation mode and the multiplexer operation mode. In this case, operation maintenance information such as device status and signal status is loaded on SDH overhead to WDM optical transmission system and receive control information.

In addition, in the external multiplexing apparatus according to the present invention, the time division multiplexer and the demultiplexer extract a virtual container from an SDH frame in a multiplexer operation mode, and multiplex / demultiplex the virtual container. do.

Hereinafter, with reference to the embodiments of the accompanying drawings will be described in detail the configuration and operation of the external multiplexing device according to the present invention.

1 shows an entire WDM optical transmission system configured by applying an external multiplexing apparatus according to the present invention. The WDM optical transmission system 10 receives a transmission signal from a client 50 and converts it into an optical signal having an assigned wavelength and inputs the same. A plurality of optical transponders 11 and 12 and different wavelengths inputted from the optical transponders 11 and 12 for converting the received optical signal of the client into a corresponding client signal and transmitting the same to the corresponding client 50. A plurality of WDM multiplexers which bundle the optical signals and multiplex them into a single optical signal or demultiplex the optical signals inputted from the optical cable, divide the optical signals into optical signals of a wavelength assigned to the client, and deliver the optical signals to each optical transponder 11 ( 13) and an optical amplifier 14 for amplifying / delivering the WDM optical signal transmitted through the optical cable connected between the WDM multiplexer 13. In the above description, the optical transponders 11 and 12 may be divided into those having a time division multiplexing function 11 and those having no time division 12. The external multiplexing device 20 according to the present invention with respect to the optical transmission system 10 is provided between the optical transponders 11 and 12 and the client 50 to bundle a plurality of low-speed client signals to transmit the optical signals. The high speed signal transmitted from the system 10 is converted, or the high speed signal inputted from the optical transmission system 10 is demultiplexed into a low speed client signal and transmitted to each client 50.

That is, among the signals of the clients 50, the high speed signal is input directly to the optical transponder 11 of the optical transmission system 10, and the low speed client signals are bundled in the external multiplexer 20 according to the present invention. The optical transmission system 10 receives only a high speed signal and performs only a wavelength division multiplexing function.

Therefore, when the client 50 does not have a transponder for requesting a new connection signal which is not currently provided in the optical transmission system 10 or for accepting the request signal, the external multiplexing device 20 according to the present invention. ) Is connected to the WDM optical transmission system 10, thereby making it simple to accept low-speed client signals.

The external multiplexing device 20 according to the present invention operates in three operation modes.

The first operation mode is a transparent transmission mode in which a client signal is transparently transmitted. In this operation mode, the external multiplexing device 20 transmits a synchronous digital hierarchy (SDH) light from the client 50. Receives a signal, converts it into an electrical signal, checks and delivers SDH frames without changing any values, aligns multiple low-speed SDH signal frames, and multiplexes one byte for each frame The SDH signal frame is transmitted to the optical transmission system 10. On the contrary, when the high speed SDH signal frame is input from the optical transmission system 10, the above process is reversed. In this transparent operation mode, the operation maintenance information including the state of the external multiplexing device 20 and the signal state must be transmitted to the WDM optical transmission system 10 through a separate line and receive control information thereof. Limitations may occur with distance to the optical transmission system 10.

The second operation mode is a repeater operation mode, which converts the SDH optical signal received from the client 50 into an electrical signal, checks the SDH frame, and checks an error state of the signal. For the SDH frame, the overhead of the repeater section is processed. Previously, as in the transparent operation mode, when multiplexing, a plurality of low-speed SDH signal frames are aligned, and then multiplexed by one byte for each frame to form a high-speed SDH signal frame and transmitted to the optical transmission system 10. When a high speed SDH frame is input from the optical transmission system 10, the above function is reversed. In this operation mode, the operation maintenance information including the state of the external multiplexing device 20 and the signal state is carried on the SDH overhead and received control information. Therefore, when operating in the repeater operation mode, a separate control line is unnecessary, and the distance from the WDM optical transmission system 10 may be large.

The third mode of operation is a multiplexer mode of operation, in which case it receives the SDH optical signal from the client 50, converts it into an electrical signal, checks the SDH frame, checks the error state of the signal, Handle overhead of frames. In addition, a virtual container (hereinafter referred to as VC) is extracted from the SDH frame and multiplexed with another. At this time, after arranging a plurality of low-speed VC, and then multiplexed by one byte for each VC to make a high-speed VC, a high-speed SDH frame is generated by attaching the SDH overhead to it. The generated high speed SDH frame is transmitted to the optical transmission system 10, and performs the above reverse function with respect to the high speed SDH frame input from the optical transmission system 10. In such a multiplexer operation mode, operational maintenance information including the state of the external multiplexer 20 and the signal state is carried on the SDH overhead and received control information. Therefore, a separate control line is unnecessary and the distance from the WDM optical transmission system 10 may be far.

Next, a specific configuration and operation of the external multiplexing device operating as described above will be described.

2 is a block diagram showing a detailed configuration of an external multiplexing device 20 according to an embodiment of the present invention.

As illustrated, the external multiplexing device 20 includes a plurality of first light / electric conversion units 21 for converting a low-speed SDH light signal input from the client 50 into an electrical signal, and the plurality of first lights. And a plurality of first bit / frame synchronizers 22 for extracting SDH frames by restoring data and clocks from the electrical SDH signals output from the pre-converter 21, and in the repeater operation mode and the multiplexer operation mode. A plurality of first framers 23 receiving SDH frames outputted from the 1-bit / frame synchronization unit 22 and processing errors, and SDH frames output from the first framer 23 when operating in the multiplexing mode. A plurality of third framers 23 that receive SDH overhead processing and a plurality of inputs from the plurality of first bit / frame synchronization units 22 or the first framers 23 or the third framers 24; Low-speed SDH Frame Multiplexed by Time Division Method A time division multiplexer 25 outputting a high speed SHD frame and outputting the high speed SHD frame, and a fifth framer 26 performing overhead processing on the high speed SDH frame output from the time division multiplexer 25 in a multiplexer operation mode; A first serial converter 27 for converting a high speed SDH frame output from the multiplexer 25 or the fifth framer 26 into a serial signal, and an electrical signal output from the first serial converter 27 A first pre / op converter 28 for converting the signal into an optical transmission system 10 and a second pre / op converter for converting a high speed SDH optical signal input from the optical transmission system 10 into an electrical signal ( 29) and a second bit / frame synchronization unit 30 for restoring data and clocks from the high speed SDH electrical signal output from the second optical / electric conversion unit 29 to extract the SDH frame, and a repeater operation mode or multiplexing. The second in a firearm operation mode The second framer 31 performs error detection and restoration on the high speed SDH frame output from the frame / frame synchronization unit 30, and the SDH frame output from the second framer 31 in the multiplexer operation mode. The fourth framer 32 performing overhead processing and the high speed SDH frames inputted from the second bit / frame synchronization unit 30 or the second framer 31 or the fourth framer 32 are demultiplexed. A time division type demultiplexer (33) outputting a low speed SDH frame of a client and a plurality of low speed SDH frames outputted from the demultiplexer (33) in a multiplexer operation mode are input to perform overhead processing on the low speed SDH frame. A plurality of sixth framers 34, a plurality of second serial converters 35 for converting low-speed SDH frames output from the demultiplexer 33 or the plurality of sixth framers 34 into serial signals, The second pre-optical conversion unit 36 converts the serial signals outputted from the plurality of second serial conversion units 35 into optical signals and transmits them to the corresponding clients 50 and the control communication port 43. An interface unit 38 for exchanging control signals for operation / maintenance / maintenance with the optical transmission system 10 and a control signal through the interface unit 38, and the plurality of framers 23, Control unit 37 for controlling the operation of the 24, 26, 31, 32, 34, and a power supply unit 39 for distributing the power supplied from the power supply port 44 to the operating power required for each block. .

The operation of the external multiplexing device 20 configured as described above is performed as follows.

The low-speed SDH optical signals input from the clients 50 are respectively input to the plurality of first optical / electric converters 21 to be converted into electrical signals, and then in each first bit / frame synchronization unit 22. The data and clock are recovered and a low speed SDH frame is extracted.

Subsequent processing depends on the operation mode.

First, when the transparent operation mode is set, the plurality of low-speed SDH frames outputted from the plurality of first bit / frame synchronization units 22 do not go through the first and third framers 23 and 24, and are directly connected to the TDM multiplexer ( 25).

When operating in the repeater operation mode, the low-speed SDH frames of the first bit / frame synchronization unit 22 pass through the first framer 23, respectively, and B1 (bit interleaved parity 1) of the SDH signal, DCC ( data communication channel), E1 (order wire), and the like are processed and input to the TDM multiplexer 25.

In addition, when operating in the multiplexer operation mode, the low-speed SDH frames of the first bit / frame synchronization unit 22 pass through the first and third framers 23 and 24, respectively, and B1 (bit) of the SDH signal. interleaved parity 1), DCC (data communication channel), E1 (order wire), and the like are processed, and SDH overheads such as B2, DCC, K1, K2, and the like are processed and input to the TDM multiplexer 25.

The TDM multiplexer 25 aligns the input SDH frames in a row and then multiplexes one byte into each frame to generate a high speed SDH frame. In this case, in the multiplexing operation mode, a high-speed VC is generated by multiplexing by byte units on the VC included in the frame instead of the frame.

As described above, the high speed SDH signal outputted from the TDM multiplexer 25 is inputted to the first serial converter 27 immediately after the SDH overhead is carried by the fifth framer 26 in the multiplexing operation mode and then in other operation modes. Converted into a serial signal, and then converted into an optical signal through the first electric / optical conversion unit 28 and then output to the optical transmission system 10. At this time, the optical signal output from the first electric / optical conversion unit 28 is a high-speed SDH optical signal.

Then, the high speed SDH optical signal input from the optical transmission system 10 is input to the second optical / pre-conversion unit 29 and converted into an electrical signal, and then data and data are transmitted by the second bit / frame synchronization unit 30. Check the SDH frame by clock recovery.

Hereinafter, similar to the processing of the low-speed client signal, in the transparent operation mode, the SDH frame confirmed by the second bit / frame synchronization unit 30 is directly transmitted to the TDM demultiplexer 33, and in the relay operation mode. After the second frame 31 is processed such as error detection and restoration, it is transmitted to the TDM demultiplexer 33. In the multiplexer operation mode, the second frame 31 passes through the second framer 31 to detect and recover the error. After the processing is performed, the data is transferred to the TDM demultiplexer 33 after the overhead processing is performed via the fourth framer 32 again.

The TDM demultiplexer 33 demultiplexes the input high speed SDH frame in the transparent operation mode and the repeater operation mode to separate and output a plurality of low speed SDH frames, and outputs the high speed VC of the input high speed SDH frame in the multiplexer operation mode. Demultiplexing is performed by separating into multiple low speed VCs.

When the signal output from the TDM demultiplexer 33 is in the multiplexer operation mode, the signal is passed through the sixth framer 34 to the plurality of second serial conversion units 35 after the overhead processing for the low-speed SDH frame is performed. In the case of the transparent operation mode or the repeater operation mode, the second serial converter 35 is directly input.

The plurality of second serial converters 35 respectively convert the input low-speed SDH frames into serial signals, which are converted into optical signals through the second pre / optical converter 36 and then to the clients 50. Is approved. The signal output from the second electric / optical converter 36 is a low speed SDH signal.

The external multiplexing device 20 may operate independently of the WDM optical transmission system 10 by including a control unit 37, an interface unit 38, and a power supply unit 39 that perform a self-control processing function.

3 is a view showing the appearance according to the embodiment of the external multiplexing device 20 of the present invention, the multiplexing device 20 is connected to the client 50, the first port 41 to send and receive a low-speed SDH optical signal ), A second port 42 for exchanging high speed signals with the WDM optical transmission system 10, and a third port 43 and a power supply port for exchanging control signals and status signals from the outside in a transparent operation mode. 44 is provided.

As described above, the external multiplexing device according to the present invention has an excellent effect of increasing transmission efficiency by efficiently accommodating low-speed client signals without directly having a WDM optical transmission system having a transponder required by a client. In particular, when time division multiplexing is further performed in the WDM optical transmission system, transmission efficiency can be further increased. In addition, since the external multiplexing apparatus according to the present invention does not have various connection standards required by the client in the WDM optical transmission system, it can have economical efficiency in the operation of the optical transponder, and is implemented in an external type, so that operation / maintenance / maintenance is possible. There is an easy excellent effect.

Claims (8)

A plurality of first optical / electric converters for converting low-speed client signals into electrical signals; A plurality of first bit / frame synchronization units for identifying a low speed SDH frame from an output signal of the first optical / pre-conversion unit; A plurality of first frames configured to perform error detection and recovery processing on a low speed SDH frame output from the first bit / frame synchronization unit; A time division multiplexer for arranging the low speed SDH frames transmitted from the plurality of first bits / frame synchronizers or the plurality of first frames in a row and outputting the high speed SDH frames; A first serial converter converting a high speed SDH frame of the time division multiplexer into a serial signal; A first pre-conversion unit converting the output signal of the first serial conversion unit into an optical signal; A second light / electric conversion unit converting the high speed SDH optical signal into an electric signal; A second bit / frame synchronization unit for checking a high speed SDH frame from an output signal of the second optical / pre-conversion unit; A second framer configured to perform error detection and restoration on a fast SDH frame output from the second bit / frame synchronizer; A time division demultiplexer for separating a high speed SDH frame output from the second bit / frame synchronization unit or a second frame into a plurality of low speed SDH frames; A plurality of second serial converters for converting a plurality of low-speed SDH frames output from the demultiplexer into a serial signal; And And a plurality of second pre / optical converters for converting and outputting serial signals outputted from the plurality of second serial converters into optical signals, The transparent operation mode in which the output of the first and second bits / frame synchronization unit is directly transmitted to the time division multiplexer and the demultiplexer, and the output of the first and second bits / frame synchronization unit through the first and second framers are time-division multiplexers. And an external multiplexing device for a wavelength division multiplexing optical transmission system, selectively performing a repeater operation mode for transmitting to a demultiplexer. delete The device of claim 1, wherein the device is A plurality of third framers which receive low-speed SDH frames from the first framer and perform SDH overhead processing; A fourth framer that receives the high speed SDH frame from the second framer and performs SDH overhead processing; A fifth framer performing overhead processing on an output signal of the time division multiplexer; And And a plurality of sixth framers for performing overhead processing on output signals from the time division demultiplexer, 1,2 bit / frame synchronization → time division multiplexer, demultiplexer → 1,2 serial converter, transparent operation mode that delivers SDH frames as they are, and 1,2 bit / frame synchronization unit → 1, 2 framer, → time division multiplexer, demultiplexer → 1, 2 serial conversion section, repeater operation mode to perform the relay function of the client transmit and receive signal, and 1, 2 bit / frame synchronization unit → Multiplexer for multiplexing client transmission / reception signals by connecting signals in order of 1st, 2nd framer → 3rd, 4th framer → time division multiplexer, demultiplexer → 5th, 6th framer → 1st, 2nd serial converter An external multiplexing device for a wavelength division multiplexing optical transmission system, characterized in that selectively operating one of the operation modes. The method according to claim 1 or 3, An interface unit for exchanging control signals for operation / maintenance / maintenance with a wavelength division multiplexing optical transmission system; A control unit configured to select an operation mode of an external multiplexing device by transmitting and receiving a control signal with a wavelength division multiplexing optical transmission system through the interface unit; And An external multiplexing device for a wavelength division multiplexing optical transmission system, characterized in that it further comprises a power supply for supplying power for the operation of the external multiplexing device. The apparatus of claim 4 wherein the device is An external multiplexing device for a wavelength division multiplexing optical transmission system, characterized in that for transmitting the operation maintenance information including the device status or signal status through a separate line other than the WDM optical transmission system and the signal line. The apparatus of claim 4 wherein the device is An external multiplexing device for a wavelength division multiplexing optical transmission system, characterized in that the operation maintenance information including the device status or signal status is carried on the SDH overhead to the WDM optical transmission system, and receives control information. The method of claim 3, wherein the time division multiplexer and demultiplexer When the multiplexer operation mode is selected, an external multiplexing apparatus for a wavelength division multiplexing optical transmission system, characterized in that the virtual container is extracted from the SDH frame and the virtual container is multiplexed / demultiplexed. The device of claim 1, wherein the device is A plurality of first ports for connecting to clients to exchange low speed SDH optical signals; A second port connected to a WDM optical transmission system for transmitting and receiving a high speed SDH signal; A third port for transmitting and receiving a control signal and a status signal from the outside; And External multiplexing device for a wavelength division multiplexing optical transmission system comprising a power supply port.

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