JP2004104547A - Carrier relay signal transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a system for transmitting a carrier relay signal by a wavelength multiplexed optical signal in which interface conditions of the transponder in a wavelength multiplexer can be conformed easily. <P>SOLUTION: The system for transmitting a carrier relay signal by a wavelength multiplexed optical signal comprises a multiplexer 2 for multiplexing carrier relay signals from a signal terminal station 1, a waveform multiplexer 4 delivering a wavelength multiplexed optical signal onto an optical transmission line 5, and a signal converter 3 for converting a multiplexed signal containing a carrier relay signal from the multiplexer 2 to conform with the interface conditions of the transponder in a wavelength multiplexer 4. The signal converter 3 comprises a section performing speed conversion by multi-point sampling of the multiplexed signal, and a scrambler for converting sampled signals such that the number of continuous "1" and "0" becomes not larger than a specified one. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a carrier relay signal transmission system for multiplexing and transmitting a carrier relay signal from a signal terminal using a system for transmitting a wavelength multiplexed optical signal.
[0002]
[Prior art]
Measure the current, phase, etc., at the transmitting and receiving terminals in the power transmission system to obtain a carrier relay signal, transmit this carrier relay signal to the monitoring unit of the power transmission system, and connect the transmitting and receiving terminals at the same time. 2. Description of the Related Art There is known a system for monitoring the normality of a power transmission system by comparing measured values based on a carrier relay signal. In the case where the carrier relay signal in this case is transmitted via a dedicated transmission path, the monitoring system is expensive, so the carrier relay signal transmission using the transmission path of the transmission system for transmitting other various information is performed. The system is common.
[0003]
FIG. 9 is an explanatory view of a main part of a conventional carrier signal transmission system, showing a case where a stuff multiplexing system is applied, where 81 is a signal terminal station, and 82 to 85 are multiplexers. The carrier relay signal from the signal terminal station 81 is, for example, a digital signal of 42 kb / s or 54 kb / s, and this carrier relay signal and a carrier relay signal from another signal terminal station (not shown) are combined. Multiplexed by a multiplexing device 82 (1.5MCRMUX) to form a multiplexed signal of 1.544 Mb / s, and this multiplexed signal and other multiplexed signals are stuff-multiplexed by a multiplexing device 83 (6 MMUX) to perform multiplexing. .312 Mb / s multiplexed signal, and this multiplexed signal and other multiplexed signals are stuff multiplexed by a multiplexing device 84 (32 MMUX) into a 32.64 Mb / s multiplexed signal. The other multiplexed signals are stuff-multiplexed by the multiplexer 85 (100 MMUX) and transmitted as a multiplexed signal of 97.728 Mb / s.
[0004]
In this carrier relay signal transmission system, the stuffing bits are inserted or deleted for each multiplexing process in the multiplexing devices 82 to 85 to perform the synchronization process. In the multiplexed signal in this case, the transmission delay time does not fluctuate due to the synchronization process, so the carrier relay signal at the same time at the transmitting and receiving end of the power transmission system can be transmitted to the monitoring unit of the power transmission system for comparison. it can.
[0005]
Further, a system for transmitting a carrier relay signal on a wavelength multiplexed optical signal by a wavelength multiplexing transmission system, for example, as shown in FIG. 10, transmits a 42 kb / s or 54 kb / s carrier relay signal from a signal terminal station 91, The multiplexed signal is multiplexed with a carrier relay signal of another station by a multiplexing device 92 (1.5MCRMUX) to obtain a multiplexed signal of 1.544 Mb / s, and this multiplexed signal and another multiplexed signal are converted into a module 93 (Mod-C). ) To obtain a multiplexed signal of 51.84 Mb / s. The multiplexed signal and another multiplexed signal are routed by a module 94 (Mod-B), and a module 95 (Mod-A) Multiplexes the multiplexed signal including the other multiplexed signal of 51.84 Mb / s into a multiplexed signal of 155.52 Mb / s. To interface with, and transmits the converted into wavelength-multiplexed optical signal at the wavelength division multiplexer 96.
[0006]
As a standardized high-speed transmission system, an SDH (Synchronous Digital Hierarchy) system is known, and a system for transmitting a carrier relay signal by applying the SDH system is also known. In this case, the carrier relay signal is multiplexed together with other information in the payload of the SDH frame. For example, a multiplexed signal of 1.544 Mb / s is multiplexed into the payload as a container, and the multiplexing start position is indicated by a pointer. Indicate by value. By multiplexing or demultiplexing another multiplexed signal as a container during transmission, the head position of the container changes, but the changed head position can be indicated by changing the pointer value.
[0007]
When the SDH method is applied, for example, the pointer value is changed by changing the container position by the route distribution or the like in the module 94 of FIG. Therefore, the pointer value is changed by buffering, and in this case, a variation in the delay time of about several μs to several tens μs may occur.
[0008]
In the carrier relay signal transmission system, it is necessary to compare the measured values at the same time at the power transmission and reception ends of the power transmission system, so that the fluctuation of the transmission delay time is severely restricted. For example, it is required to be within 20 μs. Therefore, a carrier relay signal transmission system that transmits a carrier relay signal by using a data communication channel DCC including D1 to D12 bytes of the section overhead SOH of the SDH frame when the SDH scheme is applied is known ( For example, see Patent Document 1).
[0009]
[Patent Document 1]
JP-A-5-160804 (pages 3 and 4, FIGS. 1 and 3)
[0010]
[Problems to be solved by the invention]
As described above, the carrier relay signal has a problem when multiplexed and transmitted to the above-mentioned SDH payload because the fluctuation of the transmission delay time is severely restricted as described above. In a system for transmitting a carrier relay signal using a data communication channel DCC, the data communication channel DCC used for communication between the devices in the network has a problem in that the data communication channel DCC is used as the network becomes larger. Due to an increase in the amount of communication, it may not be available for transmission of the carrier relay signal.
[0011]
In the case of a system for transmitting a carrier relay signal using a wavelength multiplex transmission system as a high-speed large-capacity transmission system, for example, as shown in FIG. 155.52 Mb / s or 622.08 Mb / s is required as an interface of the. That is, it is necessary to multiplex the carrier relay signal so as to satisfy the interface condition of the wavelength multiplexing device 96 with the transponder. For an existing wavelength multiplexing transmission system, the interface condition of the wavelength multiplexing device with the transponder is required. It is not easy to multiplex the carrier relay signal so as to satisfy
[0012]
SUMMARY OF THE INVENTION An object of the present invention is to transmit a carrier relay signal by a wavelength-division multiplexed optical signal without using stuff multiplexing or the SDH method, and as a configuration capable of easily satisfying an interface condition with a transponder of a wavelength division multiplexing device. And
[0013]
[Means for Solving the Problems]
The carrier relay signal transmission system of the present invention, which will be described with reference to FIG. 1, is a carrier relay signal transmission system that multiplexes a carrier relay signal, converts the multiplexed optical signal into a wavelength multiplexed optical signal, and transmits the multiplexed optical signal. A multiplexer 2 for multiplexing the carrier relay signals of the above, a wavelength multiplexing device 4 for transmitting a wavelength multiplexed optical signal obtained by multiplexing optical signals of a plurality of wavelengths to an optical transmission line 5, and a carrier relay signal by the multiplexer 2. And a signal conversion device 3 for converting the multiplexed signal including the multiplexed signal so as to conform to the interface conditions of the transponder of the wavelength multiplexing device 4. The signal conversion device 3 performs multipoint sampling of the multiplexed signal by the multiplexing device 2. And a sampling unit for performing speed conversion, and reducing the number of continuous "1" and "0" of the signal sampled by the sampling unit to a predetermined number or less. And it has a configuration including a scrambler to convert to.
[0014]
The signal converter 3 performs sampling at a multiple point on the multiplexed signal from the multiplexer 2 based on the clock signal of the transmission rate of the interface condition of the transponder of the wavelength multiplexing device 4 to perform speed conversion. And a scrambler for multiplying the sampled output signal from by a preset code sequence and converting the number of consecutive “1” s and “0” s of the sampled output signal to a predetermined number or less. Things.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is an explanatory view of a system according to an embodiment of the present invention. Reference numerals 1 and 9 denote signal terminals, 2 and 8 denote multiplexers, 3 and 7 denote signal converters, 4 and 6 denote wavelength multiplex devices, and 5 denote the same. 1 shows an optical transmission path. For example, when transmitting a carrier relay signal from the signal terminal station 1 to the signal terminal station 9, the multiplexer 2 multiplexes the carrier relay signal with the carrier relay signal from another signal terminal station (not shown), and the signal converter 3 transmits the wavelength. The transmission speed is set to satisfy the interface condition with the transponder of the multiplexing device 4, and the wavelength-division multiplexing device 4 on the transmitting side puts the carrier relay signal on the wavelength multiplexed optical signal and sends it out to the optical transmission line 5.
[0016]
The wavelength multiplexing device 6 on the receiving side has a function of demultiplexing the wavelength multiplexed optical signal and converting it into an electric signal corresponding to the wavelength, contrary to the wavelength multiplexing device 4 on the transmitting side. The multiplexing device 8 performs the reverse processing of the signal conversion device 3, performs the demultiplexing process reversely to the multiplexing device 2 on the transmission side, and transfers the separated carrier relay signal to the signal terminal 9. .
[0017]
FIG. 2 is an explanatory view of an embodiment of the present invention, in which 11 is a signal terminal, 12-1 to 12-4, 13 are multiplexers, 14 is a signal converter, and 15 and 16 are multiplexed signal processors. Reference numeral 17 denotes a wavelength multiplexing apparatus, and shows the configuration of the transmitting end of the signal terminal 1, the multiplexer 2, the signal converter 3, and the wavelength multiplexing apparatus 4 in FIG.
[0018]
The carrier relay signal from the signal terminal 11 is a 42 kb / s or 54 kb / s signal, and is multiplexed with a carrier relay signal from another signal terminal in the multiplexer 12-1 to 1.5 Mb / s. Signal. The multiplexing device 12-4 receives the audio signal and various data and multiplexes the signal to generate a 1.5 Mb / s signal. Similarly, multiplexers 12-2 and 12-3 (not shown) multiplex various data and the like into 1.5 Mb / s signals, and multiplex in the multiplexer 13 to 6 Mb / s signals. I do. Note that 1.5 Mb / s is a signal of 1.544 Mbs, and 6 Mb / s is a signal of 6.312 Mb / s.
[0019]
When the interface condition of the transponder of the wavelength multiplexing device 17 is 155 Mb / s, the signal conversion device 14 converts the 6 Mb / s signal from the multiplexing device 13 into a 155 Mb / s signal by multipoint sampling. In this case, since “1” or “0” is continuous for a predetermined number or more, a scramble process is performed to obtain a signal that does not include a continuous “1” or “0” for the predetermined number or more. The multiplexed signal processing units 15 and 16 have a function of interfacing a 155 Mb / s SDH signal or another multiplexed signal with a transponder of the wavelength multiplexing device 17. Also in this case, 155 Mb / s is a signal of 155.52 Mb / s.
[0020]
FIG. 3 is an explanatory view of a main part of the signal conversion device. FIG. 3A shows a signal conversion device on the transmission side, 21 is a sampling unit, 22 is a clock generation unit, 23 is a scrambler, and 24 is an interface unit (INF). Is shown. (B) shows a signal conversion device on the receiving side, 25 indicates an interface unit (INF), 26 indicates a descrambler, 27 indicates a desampling unit, and 28 indicates a clock reproducing unit.
[0021]
The signal converter 14 in FIG. 2 converts a 6 Mb / s signal from the multiplexer 13 into 155 Mb / s, which is the interface condition of the transponder of the wavelength multiplexing device 17, and FIG. The 6 Mb / s signal from the multiplexing device 13 is input to the sampling unit 21 in FIG. Then, a 6 Mb / s signal is sampled by a clock signal of a frequency of 155 MHz from the clock generator 22. Accordingly, since a 6 Mb / s multiplexed signal is sampled by a 155 MHz clock signal that is approximately 26 times as fast, "1" of the 6 Mb / s signal becomes approximately 26 consecutive "1s". The "0" of the / s signal is approximately 26 consecutive "0s".
[0022]
Therefore, a scrambling process is performed on the 155 Mb / s signal sampled at multiple points in the scrambler 25 so that the number of continuous "1" or "0" is equal to or less than a predetermined number such as eight. To process. For example, a configuration may be employed in which a sampling output signal is multiplied by a preset code string based on a generator polynomial or the like. After scrambling the multi-point sampled signal as described above, the signal is input to the transponder of the wavelength multiplexing device 17 via the interface unit 24, and is converted into an optical signal having a predetermined wavelength. The wavelength multiplexing device 17 converts 155 Mb / s signals from the other multiplexed signal processing units 15 and 16 into optical signals having different wavelengths, multiplexes different wavelengths, and transmits the multiplexed signals.
[0023]
On the receiving side, the processing opposite to that on the transmitting side is performed. The wavelength division multiplexing device separates the wavelength multiplexed optical signal received corresponding to the wavelength, and converts the optical signal of the wavelength including the carrier relay signal into an electric signal. , And input to the descrambler 26 via the interface unit 25 in FIG. 3B, return to the original multi-point sampled signal, and input to the de-sampling unit 27 and the clock reproducing unit 28. A clock of 155 MHz is extracted by the clock reproducing unit 28, frequency-divided to reproduce a 6-MHz clock signal, and the descrambled 155-Mb / s signal is returned to the original 6-Mb / s signal using this clock signal. After that, the carrier relay signal is received and processed by demultiplexing or the like.
[0024]
FIG. 4 is an explanatory view of another embodiment of the present invention, wherein 31 is a signal terminal, 32 is a carrier relay signal multiplexer (1.5MCRMUX), 33 is a signal converter, and 34 is a wavelength multiplexer. . The carrier relay signal of 42 kb / s or 54 kb / s from the signal terminal station 31 includes various data such as a current value and a phase measured at the power transmission end or the power reception end, and has a frame structure of a fixed number of bits. And a multi-frame is formed by assembling a plurality of frames and adding a multi-frame number.
[0025]
The carrier relay signal multiplexing device 32 multiplexes the carrier multiplexed signal with another carrier relay signal to generate a 1.54 Mb / s signal and inputs the multiplexed signal to the signal conversion device 33. The 1.544 Mb / s signal in this case can be a bipolar signal. The signal conversion device 33 has a configuration shown in FIG. 3A. In this signal conversion device 33, a 1.54 Mb / s signal is multi-point sampled by a clock signal of 155.54 MHz to obtain a signal of 155 .54 Mb / s, which is matched to the interface conditions of the transponder of the wavelength multiplexing device 34. The signal of 155.54 Mb / s in this case can be converted into an NRZ signal to be converted into an optical signal.
[0026]
The wavelength multiplexing device 34 also receives another signal of 155.54 Mb / s (not shown) and converts it into optical signals having different wavelengths to obtain wavelength multiplexed optical signals. In this case, if optical signals of different eight wavelengths are multiplexed, a system having a transmission rate of about 1.2 Gb / s is configured. Further, the receiving side can perform the receiving process by restoring the carrier relay signal by a process reverse to the above-described transmitting side.
[0027]
FIG. 5 is an explanatory diagram of still another embodiment of the present invention, wherein 41 is a signal terminal station, 42 is a carrier relay signal multiplexer (1.5MCRMUX), 43 is a multiplexer (6MMUX), and 44 is a signal. A converter 45 is a wavelength multiplexing device. This embodiment shows a case in which a PDH (Plesiochronous Digital Hierarchy) signal of a 1.544 Mb / s, 6.312 Mb / s, and 32.06 Mb / s system is used. The signal is multiplexed by the 42 kb / s or 54 kb / s carrier relay signal multiplexing device 42 from the station 41 to a signal of 1.544 Mb / s, and this signal is multiplexed by the multiplexing device 43 to obtain a signal of 6.32 Mb / s. A configuration is shown in which a signal is input to the signal converter 44, converted into a signal of 155.52 Mb / s as an interface condition of the transponder of the wavelength multiplexer 45, and input to the wavelength multiplexer 45.
[0028]
The signal conversion device 44 can be configured as shown in FIG. 3A, and the wavelength multiplexing device 45 converts the signal into optical signals having different wavelengths together with another 155.52 Mb / s signal. Wavelength multiplexing. Note that a configuration is also possible in which a signal of 6.32 Mb / s is further multiplexed and input to the signal conversion device 44 as a signal of 32.64 Mb / s. On the receiving side, the receiving process of the carrier relay signal is performed by a process reverse to the above-described process on the transmitting side.
[0029]
FIG. 6 is an explanatory diagram of still another embodiment of the present invention, in which 51 is a signal terminal station, 52 is a carrier relay signal multiplexer (1.5MCRMUX), 53 is a multiplexer (6MMUX), and 54 is a code. A conversion device (6 MOPTTR), 55 is a signal conversion device, and 56 is a wavelength multiplexing device.
[0030]
5. The signal is multiplexed by a 42 kb / s or 54 kb / s carrier relay signal multiplexing device 52 from the signal terminal station 51 into a 1.544 Mb / s bipolar signal, and the bipolar signal is multiplexed by a multiplexing device 53; The data is input to the encoding conversion device 54 as a 32 Mb / s bipolar signal. The encoding conversion device 54 converts the bipolar signal into a CMI code to generate a CMI signal of 12.624 Mb / s, and inputs the CMI signal to the signal conversion device 55.
[0031]
The signal conversion device 55 has, for example, the configuration shown in FIG. 3A, and converts into a 155.54 Mb / s NRZ signal of the interface condition of the transponder of the wavelength multiplexing device 56 by multipoint sampling as described above. Then, it is input to the wavelength multiplexing device 56. The wavelength multiplexing device 55 converts the signals into optical signals having different wavelengths together with the other signals of 155.52 Mb / s, and performs wavelength multiplexing. Also in this embodiment, the receiving side can perform the receiving process of the carrier relay signal by performing the reverse process of the above-described process on the transmitting side.
[0032]
FIG. 7 is an explanatory view of still another embodiment of the present invention, wherein 61 is a signal terminal station, 62 is a carrier relay signal multiplexer (1.5MCRMUX), 63 is a multiplexer (6MMUX), and 64 is multiplex. Multiplexing device (32 MMUX), 65 indicates a signal conversion device, and 66 indicates a wavelength multiplexing device.
[0033]
The signal is multiplexed by a 42 kb / s or 54 kb / s carrier relay signal multiplexing device 62 from a signal terminal station 61 into a 1.544 Mb / s bipolar signal. .32 Mb / s as a bipolar signal and input to the multiplexer 64. The multiplexing device 64 multiplexes the bipolar signal of 6.32 Mb / s into five to make a bipolar signal of 32.64 Mb / s, and inputs the bipolar signal to the signal converter 65.
[0034]
The signal converter 65 has, for example, the configuration shown in FIG. 3A, converts the signal into an NRZ signal of 622.08 Mb / s, which is the interface condition of the transponder of the wavelength multiplexer 66, and inputs the signal to the wavelength multiplexer 66. I do. The wavelength conversion device 66 converts the optical signal into an optical signal having a different wavelength together with the other NRZ signal of 622.08 Mb / s and performs wavelength multiplexing. For example, a transmission rate of about 5 Gb / s is obtained when 8 multiplexes are performed. Also in this embodiment, the receiving side can perform the receiving process of the carrier relay signal by performing the reverse process of the above-described process on the transmitting side.
[0035]
FIG. 8 is an explanatory diagram of still another embodiment of the present invention, in which 71 is a signal terminal station, 72 is a carrier relay signal multiplexer (1.5MCRMUX), 73 is a multiplexer (6MMUX), and 74 is multiplex. , A code converter (32MOPTTR), 76 a signal converter, and 77 a wavelength multiplexing device.
[0036]
The signal is multiplexed by a 42 kb / s or 54 kb / s carrier relay signal multiplexing device 72 from the signal terminal station 71 to obtain a 1.544 Mb / s bipolar signal. .32 Mb / s as a bipolar signal and input to the multiplexer 74. The multiplexing device 74 multiplexes the 6.32 Mb / s bipolar signal into five signals to obtain a 32.64 Mb / s bipolar signal, which is input to the code conversion device 75.
[0037]
The code conversion device 75 converts the bipolar signal into a CMI code, and inputs the CMI code to the signal conversion device 76 as a 64.128 Mb / s CMI signal. The signal converter 76 converts the signal into an NRZ signal of 622.08 Mb / s, which is the interface condition of the transponder of the wavelength multiplexer 77, and inputs the signal to the wavelength multiplexer 77. The wavelength conversion device 77 converts the optical signal into an optical signal having a different wavelength together with the other NRZ signal of 622.08 Mb / s and performs wavelength multiplexing. For example, a transmission rate of about 5 Gb / s is obtained when 8 multiplexes are performed. Also in this embodiment, the receiving side can perform the receiving process of the carrier relay signal by performing the reverse process of the above-described process on the transmitting side.
[0038]
【The invention's effect】
As described above, according to the present invention, the signal converter 3 which can cope with the interface condition of the transponder of the wavelength multiplexing device 4 is provided, and the signal obtained by multiplexing the carrier relay signal is input to the wavelength multiplexing device 4 and the wavelength It can be transmitted as a multiplexed optical signal, and has an advantage that a carrier relay signal can be transmitted as a wavelength multiplexed optical signal by a multiplexing method in which fluctuations in transmission delay are reduced. In the signal conversion device 3, the number of consecutive "1" s and "0s" generated by multipoint sampling increases, but the number of consecutives can be suppressed to a predetermined number or less by scrambling.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a system according to an embodiment of the present invention.
FIG. 2 is an explanatory diagram of an embodiment of the present invention.
FIG. 3 is an explanatory diagram of a main part of a signal conversion device.
FIG. 4 is an explanatory diagram of another embodiment of the present invention.
FIG. 5 is an explanatory view of still another embodiment of the present invention.
FIG. 6 is an explanatory diagram of still another embodiment of the present invention.
FIG. 7 is an explanatory diagram of still another embodiment of the present invention.
FIG. 8 is an explanatory diagram of still another embodiment of the present invention.
FIG. 9 is an explanatory diagram of a main part of a conventional carrier relay signal transmission system.
FIG. 10 is an explanatory diagram of a main part of a conventional wavelength multiplexing transmission system.
[Explanation of symbols]
1, 9 signal terminal station 2, 8 multiplexer 3, 7 signal converter 4, 6 wavelength multiplexer 5 optical transmission line 11 signal terminal stations 12-1 to 12-4, 13 multiplexer 14 signal converter 17 wavelength Multiplexer

Claims (2)

In a carrier relay signal transmission system in which a carrier relay signal is multiplexed, converted into a wavelength multiplexed optical signal and transmitted,
A multiplexer for multiplexing the carrier relay signal,
A wavelength multiplexing device for transmitting a wavelength multiplexed optical signal obtained by multiplexing optical signals of a plurality of wavelengths to an optical transmission line;
A multiplexed signal including the carrier relay signal by the multiplexing device, and a signal conversion device that converts the multiplexed signal to match the interface conditions of the transponder of the wavelength multiplexing device,
The signal conversion device includes a sampling unit that performs multipoint sampling of the multiplexed signal by the multiplexing device and performs speed conversion, and a predetermined number of consecutive “1” and “0” of the signal sampled by the sampling unit. A carrier relay signal transmission system having a configuration including a scrambler that converts the signal into the following. The signal converter includes a sampling unit that performs multipoint sampling of a multiplexed signal from the multiplexer by using a clock signal having a transmission rate of a transponder interface condition of the wavelength multiplexing device to perform speed conversion, and a signal from the sampling unit. A configuration including a scrambler that multiplies the sampling output signal by a preset code sequence and converts the number of consecutive “1” and “0” of the sampling output signal so as to be less than a predetermined number. The carrier relay signal transmission system according to claim 1, wherein:

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