KR20040037558A - Optical transponder having 2.5 Gbps, 10 Gbps, and 40 Gbps signals as tributary signals - Google Patents

Abstract

PURPOSE: A 43Gbps optical transponder having tributary signals with 2.5Gbps, 10Gbps and 40Gbps is provided to receive a 10Gbps tributary signal together with 2.5Gpbs and 10Gbps tributary signals. CONSTITUTION: A 10 Giga tributary signal converting unit(100) receives a plurality of optical signals with 10 Gbps capacity, converts the received optical signals into a plurality of 16 parallel STM-64(Synchronous Transfer Mode-64) signals. The 10 Giga tributary signal converting unit(100) converts a plurality of 16 parallel STM-64 signals into a plurality of optical signals with 10Gbps capacity. A 2.5 Giga tributary signal converting unit(110) receives a plurality of optical signals with 2.5Gbps capacity, and converts the received optical signals into a plurality of 16 parallel STM-64 signals. The 2.5 Giga tributary signal converting unit(110) converts a plurality of 16 parallel STM-64 signals into a plurality of optical signals with 2.5Gbps capacity. A main signal converting unit(120) multiplexes four 16 parallel STM-64 signals generated in the 10 Giga tributary signal converting unit(100) and the 2.5 Giga tributary signal converting unit(110), generates an optical signal having 43Gbps capacity, and outputs the generated optical signal. The main signal converting unit(120) receives an optical signal with 43Gbps capacity, generates four 16 parallel STM-16 signals, and transmits the generated four 16 parallel STM-16 signals to the 10 Giga tributary signal converting unit(100) and the 2.5 Giga tributary signal converting unit(110).

Description

Optical transponder having 2.5 Gbps, 10 Gbps, and 40 Gbps signals as tributary signals

The present invention relates to 43 Gbps optical transmission, and more particularly to a 43 Gbps optical transponder with dependent signals of 2.5 Gbps, 10 Gbps, and 40 Gbps.

An example of the configuration of a 43 Gbps optical transponder is the prototype proposed by M. Tomizawa et al. This can accept a 2.5 Gbps signal or a 40 Gbps signal as a dependent signal, but has a problem in that it cannot accept a 10 Gbps signal that is widely used.

It is an object of the present invention to provide a 43 Gbps optical transponder capable of accommodating 10 Gbps dependent signals together with 2.5 Gbps and 40 Gbps signals as dependent signals.

1 is a block diagram showing an embodiment of a 43 Gbps optical transponder according to the present invention with 2.5 Gbps and 10 Gbps optical signals as dependent signals.

FIG. 2 is a block diagram showing another embodiment of a 43 Gbps optical transponder according to the present invention with 2.5 Gbps and 10 Gbps optical signals as dependent signals.

3 is a block diagram showing yet another embodiment of a 43 Gbps optical transponder according to the present invention with a 40 Gbps optical signal as a dependent signal.

Figure 4 is a block diagram showing another embodiment of a 43 Gbps optical transponder according to the present invention with a 40 Gbps optical signal as a dependent signal.

The 43 Gbps optical transponder according to the present invention for achieving the above technical problem, receives a plurality of optical signals having a capacity of 10 Gbps to convert into a plurality of 16 parallel STM-64 signals, a plurality of 16 parallel STM-64 signals 10 Gigahertz dependent signal conversion unit for converting and outputting a plurality of optical signals having a capacity of 10 Gbps; 2.5 to receive a plurality of optical signals having a capacity of 2.5 Gbps to convert into a plurality of 16 parallel STM-64 signals, 2.5 to convert a plurality of 16 parallel STM-64 signals into a plurality of optical signals having a capacity of 2.5 Gbps Giga slave signal conversion unit; And connecting up to four 16 parallel STM-64 signals generated by the 10 Gigahertz dependent signal converter and the 2.5 Gigahertz dependent signal converter to multiplex them to generate and output an optical signal having a capacity of 43 Gbps, 43 It is preferable to include a main signal conversion unit for receiving the optical signal having a capacity of Gbps to generate four 16 parallel STM-64 signals divided by the 10 gigabytes dependent signal converter and the 2.5 gigabytes dependent signal converter.

Hereinafter, a 43 Gbps optical transponder according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing an embodiment of a 43 Gbps optical transponder according to the present invention with 2.5 Gbps and 10 Gbps optical signals as dependent signals.

Optical transponders perform the function of generating optical signals with specific wavelengths through the conversion of photo-electrical and electrical-light to accommodate client optical signals into wavelength division multiplex transmission systems. The 43 Gbps optical transponder receives the dependent signals and time-division multiplexes them to generate an optical signal of 43 Gbps, and in turn, receives the 43 Gbps optical signals and demultiplexes the dependent signals into output signals. In addition to the acceptance and multiplexing of the dependent signal, it also has a function of adding a code for error correction and overhead for management.

Referring to FIG. 1, a 43 Gbps optical transponder according to a preferred embodiment includes a 10 Gigahertz dependent signal converter 100, a 2.5 Gigahertz dependent signal converter 110, and a main signal converter 120.

The 10 Gigabit dependent signal converter 100 receives a plurality of optical signals 211 having a capacity of 10 Gbps and converts them into a plurality of 16 parallel STM-64 signals, and converts the plurality of 16 parallel STM-64 signals to 10 Gbps. The light is converted into a plurality of optical signals having a capacity and output. To this end, it is desirable to include a 10 Gbps transceiver 212 that mutually converts 10 Gbps optical signals and 16 parallel STM-64 signals.

2.5 Gigahertz signal conversion unit receives a plurality of optical signals (201-1 to 201-n, n is a natural number of 4 or less) having a capacity of 2.5 Gbps to convert into one 16 parallel STM-64, one 16 parallel The STM-64 signal is converted into a plurality of optical signals having a capacity of 2.5 Gbps and output. To this end, a plurality of 2.5 Gbps transceivers 202-1 through 202-n converting a plurality of 2.5 Gbps optical signals and electrical signals into each other, and a plurality of Gbps converting a plurality of 2.5 Gbps electrical signals into four 622 Mbps parallel signals, respectively. Demultiplexers (203-1 to 203-n), a plurality of multiplexers (205-1 to 205-n) for collecting a plurality of 622 Mbps parallel signals in parallel and converting them into 2.5 Gbps signals, and a plurality of 4 parallel It is preferred to include an STM-64 framer 204 that converts the STM-16 signal and one 16 parallel STM-64 signal to and from each other.

The main signal converter 120 connects up to four 16 parallel STM-64 signals generated by the 10 Gigahertz dependent signal converter 100 and the 2.5 Gigahertz dependent signal converter 110 to multiplex them, thereby capturing a capacity of 43 Gbps. It generates and outputs an optical signal 224 having a signal, and generates four 16 parallel STM-64 signals by receiving an optical signal having a capacity of 43 Gbps. Part 110 is delivered to. To this end, up to four multiple 16 parallel STM-64 signals are connected and converted into 16 parallel OTU-3 signals, or SFI-5 signals, and 16 parallel OTU-3 signals into four 16 parallel STM-64 signals. Converting STM-256 / OTU-3 framer 221, 16: 1 multiplexer 222 converting 16 parallel OTU-3 signals to serial OTU-3 signals, converting serial OTU-3 signals to 43 Gbps optical signals An all-optical converter 223 for converting and outputting a signal, a 1:16 demultiplexer 226 for converting a serial OTU-3 signal into 16 parallel OTU-3 signals, and converting an optical signal of 43 Gbps into a serial OTU-3 signal It is preferable to include a photoelectric converter (225).

Referring to FIG. 1, the 2.5 Gbps slave optical signal 201 is converted into an electrical signal through a transceiver 202 and then 4 parallel STM-16 signals having a capacity of 622 Mbps via a demultiplexer (Demux, 203). Is converted to. Up to four groups of these parallel signals are connected to the STM-64 framer 204, multiplexed, and output as 16 parallel 622 Mbps signals. Meanwhile, the 10 Gbps dependent optical signal 211 is converted into 16 parallel STM-64 signals having a capacity of 622 Mbps via the transceiver 212.

The 43 Gbps optical transponder according to the present invention includes a number of such transceivers 202, demultiplexers 203, and transceivers 212, through which a number of parallel STM-64 signals are generated. Up to four such parallel signals are connected to the STM-256 / OTU3 framer 221, multiplexed, and inserted into an OTU3 overhead, and then output as 16 parallel SFI-5 signals, that is, 16 parallel OTU-3 signals. This SFI-5 signal is converted to a serial 43 Gbps OTU-3 signal via a multiplexer (Mux, 222) and then output as an OTU-3 signal 224 via an all-optical converter (E / O, 223). The dependent signals that make up the OTU3 signal consist of a combination of up to four 10 Gbps signals and up to 16 2.5 Gbps signals.

The OTU-3 signal received in the reverse direction is converted into an electrical signal through the photoelectric converters (O / E, 225) and then converted into 16 parallel SFI-5 signals through the demultiplexer 226. This signal is demultiplexed in the STM-256 / OTU3 framer 221 and output as four groups of 16 parallel 622 Mbps signals. The parallel signal connected to the STM-64 framer 204 is then demultiplexed and output as a 2.5 Gbps slave signal 201 via the multiplexer 205 and the transceiver 202. The output signal of the STM-256 / OTU3 framer 221 transmitted to the transceiver 212 is output as a 10 Gbps slave signal 211.

FIG. 2 is a block diagram showing another embodiment of a 43 Gbps optical transponder according to the present invention with 2.5 Gbps and 10 Gbps optical signals as dependent signals.

In FIG. 2, the 10 Gigahertz dependent signal converter 100 and the 2.5 Gigahertz dependent signal converter 110 correspond to the 10 Gigahertz dependent signal converter 100 and 2.5 Gigahertz dependent signal converter 110 of FIG. 1, respectively.

Referring to FIG. 2, the main signal converter 120 of the 43 Gbps optical transponder according to a preferred embodiment includes a 64:16 multiplexer / demultiplexer 321, an OTU-3 framer 322, and a 16: 1 multiplexer ( 323, an all-optical converter 324, a 1:16 demultiplexer 327, and a photoelectric converter 326.

The 64:16 multiplexer / demultiplexer 321 multiplexes up to four 16 parallel STM-64 signals generated by the 10 Gigabit dependent signal converter 100 and the 2.5 Gigabit slave signal converter 110. 16 parallel STM-256 signals are generated, and four 16 parallel STM-64s are generated by demultiplexing the 16 parallel STM-256 signals generated by the OTU-3 framer 322.

The OTU-3 framer 322 generates 16 parallel OTU-3 signals by adding OTU-3 overhead to the 16 parallel STM-256 signals generated by the 64:16 multiplex / demultiplexer 321, and the demultiplexer 327 16 parallel STM-256 signals are generated by eliminating the OTU-3 overhead from the 16 parallel OTU-3 signals generated in.

The 16: 1 multiplexer 323 of FIG. 2, the all-optical converter 324, the 1:16 demultiplexer 327, and the photoelectric converter 326 of FIG. 223, 1:16 demultiplexer 226, and photoelectric converter 225.

Referring to FIG. 2, the input 2.5 Gbps dependent optical signal 301 is converted into an electrical signal via the transceiver 302 and is converted into a 622 Mbps 4 parallel STM-16 signal by the demultiplexer 303. This signal is multiplexed into STM-64 signals by the STM-64 framer 304 up to four groups, converted into 16 parallel STM-64 signals at 622 Mbps and input to the 64:16 multiplex / demultiplexer 321. Meanwhile, the 10 Gbps input optical signal 311 is converted into a 16 parallel STM-64 signal having a capacity of 622 Mbps by the transceiver 312 and input to the 64:16 multiplex / demultiplexer 321.

Up to four groups of 16 parallel signals input to the 64:16 multiplex / demultiplexer 321 are allowed to be multiplexed into 16 parallel STM-256 signals and then output as 16 parallel SFI-5 signals. The SFI-5 signal is converted into an OTU-3 signal by the OTU-3 framer 322 and output in the form of 16 parallel SFI-5 and converted into a serial OTU-3 signal by the multiplexer 323. This signal is converted into a 43 Gbps optical signal 325 by the all-optical converter 324 and output.

The 43 Gbps optical signal received in the reverse direction is converted into an electrical signal by the photoelectric converter 326 and converted into a parallel SFI-5 form by the demultiplexer 327. This signal is converted by the OTU-3 framer 322 into a 16 parallel STM-256 signal and input to the 64:16 multiplexer / demultiplexer 321 in SFI-5 form. This signal is demultiplexed into four 16 parallel STM-64 signals in a 64:16 multiplexer / demultiplexer 321 and then output as four groups of 16 parallel signals.

The signal to be output as a 10 Gbps signal is converted into an optical signal by the transceiver 312 and output. The signal to be output at 2.5 Gbps among the outputs of the 64:16 multiplex / demultiplexer 321 is demultiplexed into four STM-16 signals by the STM-64 framer 304 and output as four parallel signals of four groups. 305 is converted into a serial 2.5 Gbps signal. This signal is converted into an optical signal by the transceiver 302 and output.

3 is a block diagram showing yet another embodiment of a 43 Gbps optical transponder according to the present invention with a 40 Gbps optical signal as a dependent signal.

Referring to FIG. 3, a 43 Gbps optical transponder according to a preferred embodiment includes a 40 Gigabit dependent signal converter 130, an OTU3 signal converter 140, and a 43 Gigabit signal converter 150.

The 40 gigahertz signal conversion unit 130 receives an optical signal having a capacity of 40 Gbps and converts it into a 16 parallel STM-256 signal, and converts the 16 parallel STM-256 signals generated by the OTU3 signal conversion unit 140 to 40 Gbps. The signal is converted into an optical signal having a capacity of and output. For this purpose, the 40 Gigahertz dependent signal converter 130 preferably includes a photoelectric converter 402, a demultiplexer 403, a multiplexer 414, and an all-optical converter 415.

The OTU3 signal converter 140 converts the 16 parallel STM-256 signals generated by the 40 Gigahertz signal conversion unit 130 into 16 parallel OTU3 signals, and the 16 parallel OTU3 signals generated by the 43 Gigabit signal converter 150. Converts to 16 parallel STM-256 signals. To this end, the OTU3 signal converter 140 preferably includes a 64:16 multiplexer / demultiplexer 421 and an STM-256 / OTU3 framer 422.

The 64:16 multiplexer / demultiplexer 421 connects the 16 parallel STM-256 signals generated by the 40 Gigabit conversion unit 130 to 64 parallel 622 Mbps signals, and the STM-256 / OTU3 framer 422 The generated 64 parallel 622 Mbps signals are connected and converted into 16 parallel STM-256 signals.

The STM-256 / OTU3 framer 422 generates 16 parallel OTU3 signals by adding OTU3 overhead to 64 parallel 622 Mbps signals, and removes OTU3 overhead from the 16 parallel OTU3 signals generated by the 43 Gigabit signal converter 150. To generate 64 parallel electrical signals with a capacity of 622 Mbps.

The 43 giga signal converter 150 converts the 16 parallel OTU3 signals generated by the OTU3 signal converter 140 into optical signals having a capacity of 43 Gbps, and receives an optical signal having a capacity of 43 Gbps. Convert to a parallel OTU3 signal. For this purpose, the 43 Giga signal converter 150 preferably includes a multiplexer 404, an all-optical converter 405, a demultiplexer 413, and a photoelectric converter 412.

Referring to FIG. 3, 40 Gbps SDH dependent signals STM-256 and 401 are converted into electrical signals via a photoelectric converter 402 and then converted into 16 parallel SFI-5 signals by a demultiplexer 403. This signal is converted into a 64 parallel 622 Mbps signal via a 64:16 multiplexer / demultiplexer 421 and then converted into a 16 parallel SFI-5 signal after the OTU3 overhead is inserted by the STM-256 / OTU3 framer 422 do. This signal is converted into a serial 43 Gbps signal via a multiplexer 404 and then output as an OTU3 signal 411 through an all-optical converter 405.

Conversely, the receiving side OTU3 signal is converted into an electrical signal via the photoelectric converter 412 and converted into an SFI-5 signal by the demultiplexer 413. This signal is converted to an STM-256 signal in the form of 64 parallel 622 Mbps via an STM-256 / OTU3 framer 422 and then converted to an SFI-5 signal by a 64:16 multiple / demultiplexer 421. This signal is converted to a 40 Gbps serial signal via a multiplexer 414 and then output as an STM-256 dependent signal through an all-optical converter 415.

Figure 4 is a block diagram showing another embodiment of a 43 Gbps optical transponder according to the present invention with a 40 Gbps optical signal as a dependent signal.

In FIG. 4, the 40 Gigahertz dependent signal converter 130 and the 43 Gigabit signal converter 150 correspond to the 40 Gigahertz dependent signal converter 130 and 43 Gigabit signal converter 150 of FIG. 3. The OTU3 signal converter 140 preferably includes an OTU3 framer 521 which mutually converts 16 parallel STM-256 signals and 16 parallel OTU3 signals.

Referring to FIG. 4, the 40 Gbps optical signal 501 is converted into an electrical signal through the photoelectric converter 502. The signal is converted into the SFI-5 form by the demultiplexer 503, and is converted into the OTU3 signal by the OTU3 framer 521 and outputted in the SFI-5 form. This signal is converted into a serial OTU3 signal by the multiplexer 504 and converted into a 43 Gbps optical signal 511 by the all-optical converter 505 and output.

The 43 Gbps signal input in the reverse direction is converted into an electrical signal by the photoelectric converter 512 and then converted into the SFI-5 form by the demultiplexer 513. This signal is converted into a 16 parallel STM-256 signal by the OTU3 framer 521, outputted in SFI-5 form, and converted by the multiplexer 514 into a serial STM-256 signal. This signal is converted into a 40 Gbps optical signal by the all-optical converter 515 and output.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

According to the 43 Gbps optical transponder according to the present invention, it is possible to accommodate the 10 Gbps dependent signal with the 2.5 Gbps and 40 Gbps dependent signals, thereby enabling the implementation of an efficient 43 Gbps OTU3 transponder.

Claims (6)

10 that receives a plurality of optical signals having a capacity of 10 Gbps and converts them into a plurality of 16 parallel STM-64 signals, converts the plurality of 16 parallel STM-64 signals into a plurality of optical signals having a capacity of 10 Gbps, and outputs 10 Giga slave signal conversion unit; 2.5 to receive a plurality of optical signals having a capacity of 2.5 Gbps to convert into a plurality of 16 parallel STM-64 signals, 2.5 to convert a plurality of 16 parallel STM-64 signals into a plurality of optical signals having a capacity of 2.5 Gbps Giga slave signal conversion unit; And Up to four 16 parallel STM-64 signals generated by the 10 gigahertz signal conversion unit and the 2.5 gigahertz signal conversion unit are multiplexed to generate and output an optical signal having a capacity of 43 Gbps, and 43 Gbps. A main signal converter for generating four 16 parallel STM-64 signals by receiving an optical signal having a capacity of and transmitting the divided signals to the 10 GSI-dependent signal converter and the 2.5 GSI-dependent signal converter; Gbps optical transponder. The method of claim 1, wherein the 2.5 Gigahertz dependent signal converter, It receives a plurality of optical signals having a capacity of 2.5 Gbps, and converts them into a plurality of four parallel STM-16 signals, and converts and outputs a plurality of four parallel STM-16 signals into a plurality of optical signals having a capacity of 2.5 Gbps. Giga photoelectric conversion unit; And Multiplexing the plurality of 4 parallel STM-16 signals generated by the 2.5 Gigaphotoelectric conversion unit into a plurality of 16 parallel STM-64 signals, and the plurality of 16 parallel STM-64 signals generated by the main signal conversion unit 4 A 43 Gbps optical transponder comprising an STM-64 framer unit converting the parallel STM-16 signal to the 2.5 Gigaphotoelectric conversion unit. The method of claim 1, wherein the main signal converter, Connect up to four 16 parallel STM-64 signals generated by the 10 Gigahertz dependent signal converter and the 2.5 Gigahertz dependent signal converter to convert them into 16 parallel OTU3 signals, and convert the 16 parallel OTU3 signals into four 16 parallel STM signals. An OTU3 overhead processing unit converting the signal into a -64 signal and transferring the 10 Gigabit dependent signal converter and the 2.5 Gigabit dependent signal converter; And Converts the 16 parallel OTU3 signals generated by the OTU3 overhead processor into an optical signal having a capacity of 43 Gbps, outputs an optical signal having a capacity of 43 Gbps, converts the 16 parallel OTU3 signals into a 16 parallel OTU3 signal, and outputs the OTU3 overhead processor. 43 Gbps optical transponder comprising a 43 gigaphotoelectric conversion unit for transmitting to. The method of claim 3, wherein the OTU3 overhead processing unit, Multiplex the input electrical signals and add 16 OTU3 overheads to generate 16 parallel OTU3 signals, and remove and demultiplex OTU3 overheads from the 16 parallel OTU3 signals generated by the 43 GV photoelectric conversion unit to provide four 16 parallel STM- 43 Gbps optical transponder, characterized by generating 64 signals. A 40 gigahertz signal conversion unit for receiving an optical signal having a capacity of 40 Gbps and converting the optical signal into a 16 parallel STM-256 signal, and converting the 16 parallel STM-256 signal into an optical signal having a capacity of 40 Gbps; OTU3 converts the 16 parallel STM-256 signal generated by the 40 GSI-dependent signal converter into 16 parallel OTU3 signals, converts the 16 parallel OTU3 signals into 16 parallel STM-256 signals, and delivers the 40 GSI-dependent signal converter Signal conversion unit; And The 16 parallel OTU3 signal generated by the OTU3 signal converter is converted into an optical signal having a capacity of 43 Gbps, and is outputted. The optical signal having a capacity of 43 Gbps is inputted and converted into a 16 parallel OTU3 signal. A 43 Gbps optical transponder comprising a 43 gigabit signal converter for transmitting to. The method of claim 5, wherein the OTU3 signal conversion unit, 16 parallel STM-256 signals generated by the 40 gigahertz signal conversion unit are connected to 64 parallel electrical signals having a capacity of 622 Mbps, and 16 parallel STM are connected by connecting 64 parallel signals having a capacity of 622 Mbps. A multiplexer for generating a -256 signal and transferring the signal to the 40 GSI-dependent signal converter; And 16 parallel OTU3 signals are generated by adding OTU3 overhead to 64 parallel signals having a capacity of 622 Mbps generated by the multiplexer, and removing the OTU3 overhead from the 16 parallel OTU3 signals generated by the 43 Gigabit signal converter. A 43 Gbps optical transponder comprising an OTU3 overhead processing unit for generating 64 parallel electrical signals having a capacity of 622 Mbps and delivering them to the multiplexer.