JP6310182B2 - Optical transmission equipment - Google Patents

Description

  The present invention relates to a multi-frequency band shared optical transmission device, and more particularly to an optical transmission device capable of reducing an optical transmission capacity.

[Conventional technology]
The conventional optical transmission apparatus employs the following method to transmit multi-system signals.
As a first method, there is a method using a multi-path optical transmission line without data compression or using a high transmission rate optical transceiver module (SFP: Small Form Factor Pluggable).
Further, as a second method, there is a method in which data compression is uniformly performed on signals of all systems.

[Conventional optical transmission apparatus: FIG. 5]
A conventional optical transmission apparatus will be described with reference to FIG. FIG. 5 is an image diagram of a conventional optical transmission apparatus.
In the conventional optical transmission apparatus, as shown in FIG. 5, a master station 100 and a slave station 200 are connected by an optical transmission line 11.
In the optical transmission apparatus of FIG. 5, data compression is not performed, and transmission between the master station 100 and the slave station 200 is four times (4 ×).

The master station 100 includes a signal processing unit 8, a combining / separating circuit (SERDES unit) 9, and an electrical / optical conversion transmitting / receiving unit (SFP unit) 10.
The signal processing unit 8 inputs data of the operators A to D, performs signal processing, outputs the data to the SERDES unit 9, and performs signal processing of the signal from the SERDES unit 9 to output the data of the operators A to D. .

The SERDES unit 9 converts the signal input in parallel from the signal processing unit 8 into a serial signal and outputs it to the SFP unit 10, converts the serial signal from the SFP unit 10 into a parallel signal, and outputs the parallel signal to the signal processing unit 8. .
The SFP unit 10 converts the signal from the SERDES unit 9 from an electric signal to an optical signal, multiplexes the signal on the optical transmission line 11 and transmits it, receives the optical signal from the optical transmission line 11 and converts it to an electric signal. The data is output to the SERDES unit 9. Here, the SFP unit 10 is for quadruple (4 ×) transmission.

The slave station 200 includes an SFP unit 12, a SERDES unit 13, and a signal processing unit 14.
The SFP unit 12 receives the optical signal from the optical transmission line 11, converts it into an electrical signal, outputs it to the SERDES unit 13, converts the signal from the SERDES unit 13 from an electrical signal to an optical signal, and converts the optical signal into the optical transmission line 11. Multiplexed and transmitted. The SFP unit 12 is also used for quadruple (4X) transmission.

The SERDES unit 13 converts the serial signal from the SFP unit 12 into parallel and outputs it to the signal processing unit 14, converts the signal input in parallel from the signal processing unit 14 into serial and outputs it to the SFP unit 12. .
The signal processing unit 14 performs signal processing on the signal from the SERDES unit 13 and outputs the signal as data of the operators A to D. The signal processing unit 14 inputs the data of the operators A to D, performs signal processing, and outputs the data to the SERDES unit 13. .

[Related technologies]
As related prior art, Japanese Patent Laid-Open No. 10-322301, “Multiplexer” (Hitachi, Ltd.) [Patent Document 1], Japanese Patent Laid-Open No. 11-177436, “Data Communication Device” (Kokusai Electric Co., Ltd.) There is [Patent Document 2].

In Patent Document 1, a multiplexing device calculates a total sum of the communication speeds of the number of low-speed terminals currently communicating, and compresses the low-speed terminals that have already started communication with the low-speed terminals that have started communication. It is shown that the compression ratio is optimized.
Patent Document 2 discloses that in a data communication apparatus, media data is compressed and encoded, multiplexed and transmitted, and multiplexed data is received, separated, and decoded.

Japanese Patent Laid-Open No. 10-322301 Japanese Patent Laid-Open No. 11-177436

However, the conventional optical transmission apparatus has the following problems.
In the conventional first method, a multipath optical transmission line requires a plurality of SFP units and optical transmission lines, and also requires a high transmission rate SFP unit, resulting in an expensive system. was there.

  Further, in the conventional second method, if data compression is uniformly performed on signals of all systems, there is a problem that it becomes difficult to satisfy the standard for a signal having a strict signal standard.

  Patent Documents 1 and 2 do not describe reducing the optical transmission capacity while satisfying signal standards.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an optical transmission apparatus capable of reducing the optical transmission capacity while satisfying the signal standard when optical transmission is performed for multi-frequency sharing.

The present invention for solving the problems of the conventional example described above is an optical transmission apparatus that synthesizes signals of different frequency bands from a plurality of wireless communication units and transmits them using an optical transmission line. A first optical transceiver module that connects, converts an electrical signal into an optical signal and outputs the optical signal to an optical transmission line, and stores a compression rate of data that satisfies the signal standard of the RF characteristics of each wireless communication unit for each wireless communication unit A table is provided for processing signals from a plurality of wireless communication units, and the compression rate for the signals from each wireless communication unit is changed to the compression rate stored in the table within the range of the processing capability of the first optical transceiver module. A first signal processing unit that compresses the signal according to the compression ratio and a signal for each wireless communication unit compressed by the first signal processing unit, and combines the first light And having a first conversion unit for outputting the run transceiver module.

  The present invention is characterized in that, in the optical transmission device, the first signal processing unit changes the compression rate set in the table in accordance with the state of data input from the wireless communication unit.

  According to the present invention, in the above optical transmission device, a second optical transceiver module that inputs an optical signal from an optical transmission path and converts it into an electrical signal, and an electrical signal from the second optical transceiver module are separated for each wireless communication unit. And a second signal processing unit that decompresses a signal from the second conversion unit at a decompression rate corresponding to the compression rate of each wireless communication unit.

According to the present invention, in the optical transmission device, the second signal processing unit compresses signals from the plurality of wireless communication units at a compression rate for each wireless communication unit, and the second conversion unit performs the second signal processing. the signal for each wireless communication unit compressed in part by combining the second optical transceiver module, and converts the electrical signal from the second conversion unit into an optical signal and outputs to the optical transmission line .

According to the present invention, there is provided an optical transmission device that synthesizes signals of different frequency bands from a plurality of wireless communication units and transmits them using an optical transmission line, wherein the first optical transceiver module is connected to the optical transmission line. Then, the electrical signal is converted into an optical signal and output to the optical transmission line, and the first signal processing unit stores the compression rate of the data that satisfies the signal standard of the RF characteristic of each wireless communication unit for each wireless communication unit. A table is provided for processing signals from a plurality of wireless communication units, and the compression rate for the signals from each wireless communication unit is changed to the compression rate stored in the table within the range of the processing capability of the first optical transceiver module. The first conversion unit synthesizes the signals for each wireless communication unit compressed by the first signal processing unit, and compresses the signal according to the compression rate. Since it is assumed to be output to the module, while satisfying the signal standards of RF characteristics of each radio communication unit, there is an effect of reducing the optical transmission capacity.

It is an image figure of a 1st optical transmission apparatus. It is an image figure of a 2nd optical transmission apparatus. It is one Example of the block diagram of a structure of this optical transmission apparatus. It is an image figure of a 3rd optical transmission apparatus. It is an image figure of the conventional optical transmission apparatus.

Embodiments of the present invention will be described with reference to the drawings.
[Outline of the embodiment]
An optical transmission apparatus according to an embodiment of the present invention combines signals from a plurality of wireless communication units and transmits them using an optical transmission path. A first optical transceiver module that converts the signal into an optical signal and outputs the optical signal to an optical transmission line, and processes signals from a plurality of wireless communication units, and performs wireless communication within the processing capability of the first optical transceiver module. A first signal processing unit that assigns the compression rate of the signal from the unit by changing the compression rate, and synthesizes the signal for each wireless communication unit compressed by the first signal processing unit and compressing the signal according to the compression rate, A first converter for outputting to the first optical transceiver module, and receiving at the slave station an optical signal from the optical transmission path and converting it into an electrical signal; And a second signal processing unit that decompresses the electrical signal at a decompression rate corresponding to the compression rate of the first signal processing unit and outputs the decompressed signal to the corresponding wireless communication unit, and satisfies the signal standards However, the optical transmission capacity can be reduced.

[First optical transmission apparatus: FIG. 1]
A first optical transmission apparatus (first optical transmission apparatus) according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is an image diagram of a first optical transmission apparatus.
As shown in FIG. 1, the basic configuration of the first optical transmission apparatus is the same as that shown in FIG. 5, but the processing contents of the signal processing units 8 and 14 are different from those shown in FIG.

Specifically, the signal processing unit 8 of the master station 100 inputs the data of the operators A to D, performs signal processing, and within the range of the transmission processing capability (X transmission) of the SFP unit 10, The data is uniformly compressed (compressed to X / 4) according to the signal and output to the SERDES unit 9.
The signal processing unit 8 decompresses the data (data compressed to X / 4) from the SERDES unit 9 (extends to X data), performs signal processing, and outputs the data as data of the operators A to D.

Then, the signal processing unit 14 of the slave station 200 decompresses the data (data compressed to X / 4) from the SERDES unit 13 (extends to X data), and performs signal processing as data of the operators A to D. Output.
Further, the signal processing unit 14 inputs data of the operators A to D, performs signal processing, and uniformly transmits data according to the number of operators within the range of the transmission processing capability (X transmission) of the SFP unit 12. Compression (compression to X / 4) is performed and output to the SERDES unit 13.

In the first optical transmission apparatus, the SERDES unit 9 converts the compressed data (X / 4 compressed data) from the signal processing unit 8 from parallel to serial, and converts the X data (X / 4 compressed data × 4) into SFP. It is output to the unit 10 and can be used for X transmission in the SFP unit 10 and the optical transmission line 11.
The SERDES unit 13 converts the compressed data (X / 4 compressed data) from the signal processing unit 14 from parallel to serial, and outputs X data (X / 4 compressed data × 4) to the SFP unit 12. The SFP unit 12 and the optical transmission line 11 can be used for X transmission.

  As described above, in the first optical transmission device, the SFP unit 10, the transmission path 11, and the SFP unit 12 can be used for X transmission, so that the transmission capacity can be reduced with an inexpensive configuration.

[Second optical transmission device: FIG. 2]
A second optical transmission apparatus (second optical transmission apparatus) according to an embodiment of the present invention will be described with reference to FIG. FIG. 2 is an image diagram of the second optical transmission apparatus.
As shown in FIG. 2, the basic configuration of the second optical transmission apparatus is the same as that shown in FIG. 1, but the processing contents of the signal processing units 8 and 14 are different from those shown in FIG.

Specifically, the signal processing unit 8 of the master station 100 inputs the data of the operators A to D, performs signal processing, and within the range of the transmission processing capability (X transmission) of the SFP unit 10, for each operator. The data is compressed in accordance with the data and output to the SERDES unit 9. In FIG. 2, the data of business operators A and B are compressed to 1/3, and the data of business operators C and D are compressed to 1/6.
The signal processing unit 8 decompresses the data (compressed data) from the SERDES unit 9 at a decompression rate determined for each business operator, performs signal processing, and outputs the data as business operators A to D. In FIG. 2, the data of business operators A and B are expanded three times, the data of business operators C and D are expanded six times, and all are output as X data.

Then, the signal processing unit 14 of the slave station 200 decompresses the data (compressed data) from the SERDES unit 13, performs signal processing, and outputs the data as data of the operators A to D. The data of business operators A and B is expanded 3 times, the data of business operators C and D is expanded 6 times, and all are output as X data.
Further, the signal processing unit 14 inputs data of the operators A to D, performs signal processing, and compresses the data according to each operator within the range of the transmission processing capability (X transmission) of the SFP unit 12. And output to the SERDES unit 13. The data of business operators A and B are compressed to 1/3, and the data of business operators C and D are compressed to 1/6.

In the second optical transmission apparatus, the SERDES unit 9 converts the compressed data (X / 3, X / 3, X / 6, X / 6 compressed data) from the signal processing unit 8 from parallel to serial, X data (X / 3 + X / 3 + X / 6 + X / 6 compressed data) is output to the SFP unit 10 and can be used for X transmission in the SFP unit 10 and the optical transmission line 11.
Further, the SERDES unit 13 converts the compressed data (X / 3, X / 3, X / 6, X / 6 compressed data) from the signal processing unit 14 from parallel to serial to obtain X data (X / 3 + X / 3 + X / 6 + X / 6) is output to the SFP unit 12 and can be used for X transmission in the SFP unit 12 and the optical transmission line 11.

However, if the data is compressed / decompressed, the signal characteristics deteriorate. Specifically, the delay amount increases and the EVM (error vector amplitude) value deteriorates. Hereinafter, the delay amount and the EVM value are RF (radio frequency) characteristics.
In the first optical transmission apparatus, the data of the operator is uniformly compressed / decompressed, which is disadvantageous for the signal of the operator having a strict signal standard for RF characteristics.
On the other hand, in the second optical transmission apparatus, strict signal standards are satisfied by weighting the data of a provider with strict RF characteristics so as to reduce the compression rate and decompression rate in the signal processing unit 8. Can do.

The weighting of the compression rate and the decompression rate in the signal processing unit 8 is set individually for each operator by the user connecting a PC (Personal Computer) to the signal processing unit 8.
In addition, the weights for each business operator are determined in advance, and the signal processing units 8 and 14 recognize that the unit or the board (board) for each business operator is mounted on the master station and the slave station when the power is turned on. In this case, the weighting value may be read from the memory storing the compression / decompression weighting provided in the unit or board and set in the correspondence table for each company.

As described above, in the second optical transmission apparatus, the SFP unit 10, the transmission path 11, and the SFP unit 12 can be used for X transmission, so that the transmission capacity can be reduced with an inexpensive configuration.
In addition, the second optical transmission apparatus can reduce the data compression rate for signals with strict RF characteristic signal standards, and can increase the data compression rate for signals with less strict signal standards. This has the effect of satisfying the characteristic signal standard and reducing the transmission capacity.

[One Example of Configuration Block Diagram of Present Optical Transmission Device: FIG. 3]
Next, an optical transmission apparatus (present optical transmission apparatus) according to an embodiment of the present invention will be described with reference to FIG. FIG. 3 is an example of a configuration block diagram of the optical transmission apparatus.
As shown in FIG. 3, the present optical transmission apparatus includes base stations (BTS A to D) 1 -A to D of business operators A to D, a master station 100, an optical transmission line 11, and a slave station 200. Have.
The optical transmission path 11 is a communication path such as an optical fiber for transmitting a digital optical signal between the master station 100 and the slave station 200.

[Each part of this optical transmission equipment]
[Master station 100]
The master station 100 includes downlink input / uplink output units 2-A to D connected to the base stations 1-A to D, duplexers (DUP) 3-A to D, and an RF / IF conversion unit 4-A. To D, A / D converters 5-A to D, IF / RF converters 6-A to D, D / A converters 7-A to D, a signal processor 8, and a combining / separating circuit ( A SERDES unit) 9 and an optical transceiver unit (SFP unit) 10.

The downlink input / uplink output units 2-A to 2-D are input / output terminal units that are connected to the base stations 1-A to D by wires.
Duplexers (DUP) 3-A to D output input signals from downlink input / uplink output units 2-A to D to RF / IF conversion units 4-A to D, and IF / RF conversion unit 6-A. The input signals from .about.D are output to the downlink input / uplink output units 2-A to D.

The RF / IF converters 4-A to D down-convert the downstream RF band signals from the duplexers 3-A to D into IF band signals and output the signals to the A / D converters 5-A to D.
The A / D conversion units 5-A to D convert the downstream IF band signals from the RF / IF conversion units 4-A to D into digital signals and output the digital signals to the signal processing unit 8.

The IF / RF conversion units 6-A to 6D up-convert the upstream IF band signals from the D / A conversion units 7-A to 7D to RF band signals and output them to the duplexers 3-A to D.
The D / A converters 7 -A to 7 -D convert the upstream digital signal from the signal processor 8 into an analog signal of the IF band signal and output it to the IF / RF converters 6 -A to 6 -D.

The signal processing unit 8 performs arithmetic processing on the digital signal to compress / decompress data.
Specifically, the signal processing unit 8 stores a compression rate / decompression rate correspondence table corresponding to the provider in the storage unit, and the A / A according to the compression rate for each provider set in the correspondence table. The transmission data from the D conversion units 5-A to D is compressed, and the received data from the SERDES unit 9 is decompressed according to the decompression rate for each business set in the correspondence table.

  Here, the compression rate of the signal processing unit 8 is set within the range of the transmission processing capability of the SFP unit 10. That is, the value obtained by adding the compression ratios of the operators (X / 3 + X / 3 + X / 6 + X / 6 in the example of FIG. 2) is within the value of the transmission processing capability (X transmission) of the SFP unit 10.

Furthermore, the signal processing unit 8 monitors the input status of each business operator data, and changes the compression rate of the correspondence table according to the input status. In this case, the signal processing unit 8 notifies the signal processing unit 14 of the slave station 200 of the change of the compression rate / decompression rate before changing the compression rate, and the compression rate and the decompression of the correspondence table of the signal processing unit 14. Let the rate change.
Thereby, the signal processing part 8 can change a compression rate according to the utilization condition of provider data, and there exists an effect which can optimize transmission efficiency.

  The decompression rate of the correspondence table stored in the signal processing unit 8 corresponds to the compression rate of the correspondence table stored in the signal processing unit 14 of the slave station 200. In other words, the data compressed by the signal processing unit 14 is returned to the original data by the signal processing unit 8. For example, if the compression rate is 1/4, the decompression rate (expansion rate) is quadrupled. .

The combining / separating circuit (SERDES unit) 9 inputs signals for each operator from the signal processing unit 8 in parallel, converts (synthesizes) them in series, and outputs them to the SFP unit 10.
Further, the SERDES unit 9 converts (separates or distributes) the serial signal from the SFP unit 10 into a signal for each operator in parallel and outputs the signal to the signal processing unit 8.

The optical transceiver unit (SFP unit) 10 converts a signal (electric signal) from the SERDES unit 9 into an optical signal, performs optical division multiplexing, and transmits the optical signal to the optical transmission line 11.
The SFP unit 10 converts the optical signal from the optical transmission line 11 into an optical signal by optical wavelength division multiplexing, and outputs it to the SERDES unit 9.

  Downlink input / uplink output units 2-A to D, duplexers (DUP) 3-A to D, RF / IF conversion units 4-A to D, and A / D conversion units 5-A to D The IF / RF converters 6-A to D and the D / A converters 7-A to D constitute a wireless communication unit of the master station 100.

[Slave station 200]
The slave station 200 includes an optical transceiver unit (SFP unit) 12, a combining / separating circuit (SERDES unit) 13, a signal processing unit 14, D / A conversion units 15-A to 15D, and an IF / RF conversion unit 16- A to D, A / D converters 17-A to D, RF / IF converters 18-A to D, duplexers (DUP) 19-A to D, and downlink output / uplink input unit 20 -A to D.

The optical transceiver unit (SFP unit) 12 converts the optical signal from the optical transmission line 11 into an optical signal by optical wavelength division multiplexing, and outputs it to the SERDES unit 13.
The SFP unit 12 converts the electrical signal from the SERDES unit 13 into an optical signal, performs optical division multiplexing, and transmits the optical signal to the optical transmission line 11.

The synthesizing / separating circuit (SERDES unit) 13 converts (separates or distributes) the serial signal from the SFP unit 12 into a signal for each business operator in parallel and outputs the signal to the signal processing unit 8.
In addition, the SERDES unit 13 inputs signals for each operator from the signal processing unit 14 in parallel, converts (synthesizes) them in series, and outputs them to the SFP unit 12.

The signal processing unit 14 performs an arithmetic process on the digital signal to compress and decompress the data.
Specifically, the signal processing unit 14 stores a compression rate / decompression rate correspondence table corresponding to the operator in the storage unit, and the SERDES unit according to the decompression rate for each operator set in the correspondence table. The received data from 13 is decompressed, and the transmission data from the A / D converters 17-A to 17-D is compressed according to the compression rate for each business set in the correspondence table.
The decompression rate of the correspondence table stored in the signal processing unit 14 corresponds to the compression rate of the correspondence table stored in the signal processing unit 8 of the master station 100, and the data compressed by the signal processing unit 8 is The signal processor 14 restores the original.

The D / A conversion units 15-A to 15-D convert the downstream digital signal from the signal processing unit 14 into an analog signal of the IF band signal and output the analog signal to the IF / RF conversion units 16-A to 16-D.
The IF / RF conversion units 16-A to 16D up-convert the downlink IF band signals from the D / A conversion units 15-A to 15D to RF band signals and output the signals to the duplexers 19-A to 19D.

The A / D conversion units 17 -A to 17 -D convert the uplink IF band signals from the RF / IF conversion units 18 -A to 18 -D into digital signals and output the digital signals to the signal processing unit 14.
The RF / IF converters 18-A to 18-A to D down-convert the uplink RF band signals from the duplexers 19-A to 19D into IF band signals and output them to the A / D converters 17-A to 17D.

The duplexers (DUP) 19-A to D output the input signals from the IF / RF conversion units 16-A to 16D to the downlink output / uplink input units 20-A to D, and the downlink output / uplink input unit 20- Input signals from A to D are output to the RF / IF converters 18 -A to 18 -D.
The downlink output / uplink input units 20-A to 20D are connected to each antenna so that a radio communication terminal corresponding to the operator can perform radio communication.

  D / A converters 15-A to D, IF / RF converters 16-A to D, A / D converters 17-A to D, RF / IF converters 18-A to D, The duplexers (DUP) 19-A to D and the downlink output / uplink input units 20-A to D constitute a radio communication unit of the slave station 200.

[Compression / decompression]
As a compression method, for example, a method is used in which high-frequency components of a signal subjected to discrete cosine transform are cut (high-frequency components are approximated to 0 value), and data is compressed by bit rounding processing.
As the decompression method, a method is used in which data is expanded by performing bit extension processing, inserting a zero value, and performing inverse discrete cosine transform.
Here, an example of the compression / decompression scheme is shown, but the present invention is not limited to the above scheme, and other compression / decompression schemes may be used.

[Signal processing of this optical transmission device]
Next, signal processing in this optical transmission apparatus will be described.
First, the flow of signal processing will be described taking the operator A as an example. A downlink signal from the base station 1-A is input from the downlink input / uplink output unit 2-A of the master station 100, and a duplexer (DUP) 3- The signal is input to the signal processing unit 8 via A, the RF / IF conversion unit 4-A, and the A / D conversion unit 5-A.

  The signal processing unit 8 performs arithmetic processing, refers to the compression rate / decompression rate correspondence table, compresses the data of the operator A at the compression rate of the operator A, performs parallel serial conversion in the SERDES unit 9, and performs data conversion. Are converted into a digital optical signal by the SFP unit 10, and optically division multiplexed with the upstream signal and transmitted as a digital optical signal to the slave station 200 via the optical transmission line 11.

  In the slave station 200, the SFP unit 12 performs optical wavelength division multiplexing on the upstream signal and converts it into a digital electric signal, the SERDES unit 13 performs serial / parallel conversion to separate the data, and the signal processing unit 14 performs arithmetic processing. And decompressing the data of the operator A at the decompression rate of the operator A with reference to the correspondence table of the compression rate and the decompression rate, the D / A conversion unit 15-A, the IF / RF conversion unit 16-A, The signal is output from the downlink output / uplink input unit 20-A to the antenna via the duplexer (DUP) 19-A.

Further, the uplink signal is input from the antenna to the downlink output / uplink input unit 20-A of the slave station 200, and the duplexer (DUP) 19-A, the RF / IF conversion unit 18-A, and the A / D conversion unit. The signal is input to the signal processing unit 14 via 17-A.
Then, the signal processing unit 14 performs arithmetic processing, refers to the compression rate / decompression rate correspondence table, compresses the data of the operator A at the compression rate of the operator A, and performs the parallel serial conversion in the SERDES unit 13. Then, the data is combined, converted into a digital optical signal by the SFP unit 12, optically multiplexed with the downstream signal, and transmitted to the master station 100 via the optical transmission line 11 as a digital optical signal.

  In the master station 100, the SFP unit 10 performs optical wavelength division multiplexing on the downstream signal and converts it to a digital electric signal, and the SERDES unit 9 performs serial / parallel conversion to separate the data, and the signal processing unit 8 performs arithmetic processing. The data of the operator A is decompressed at the decompression rate of the operator A with reference to the compression rate / decompression rate correspondence table, the D / A conversion unit 7-A, the IF / RF conversion unit 6-A, The data is output from the downlink input / uplink output unit 2-A to the base station 1-A via the duplexer (DUP) 3-A.

  Thus, in the signal processing unit 8, the compression rate / decompression rate is set in the correspondence table for each business operator, and the signal processing unit 8 compresses the data at the compression rate set for each business operator, Since the processing unit 14 is decompressed at the decompression rate for each provider with reference to the correspondence table, the compression rate is reduced for signals with strict signal standards, and the compression rate is increased if the signal standards are not strict, The optical transmission capacity can be reduced while satisfying the signal standards.

[Third optical transmission device: FIG. 4]
Next, a third optical transmission apparatus (third optical transmission apparatus) according to the embodiment of the present invention will be described with reference to FIG. FIG. 4 is an image diagram of the third optical transmission apparatus.
As shown in FIG. 4, the third optical transmission apparatus includes a plurality of optical transmission lines 11a. 11b is used to connect the master station 100 and the slave station 200, and the master station 100 is provided with SFP units 10a and 10b and the slave station 200 is provided with SFP units 12a and 12b corresponding to the transmission paths 11a and 11b. ing.
The SFP units 10a, 10b, 12a, and 12b are 2X transmission optical transceiver units.

The signal processing units 8 and 14 perform signal processing but do not perform compression and decompression.
The SERDES unit 9 combines the data of two operators out of the signals from the signal processing unit 8 (data of the four operators / X data in FIG. 4) (synthesizes the data into 2X data), and the SFP unit 10a or 10b. To distribute.
The SERDES unit 9 separates the combined data (2X data) of the two operators from the SFP units 10a and 10b and outputs the combined data (X data) of each operator to the signal processing unit 8 in parallel.

And the SERDES part 13 isolate | separates 2X data from SFP part 12a, 12b, and outputs it to the signal processing part 14 in parallel with each provider's data (X data).
The SERDES unit 13 combines (combines with 2X data) the data of the two operators out of the signal (X data) from the signal processing unit 14 and distributes the data to the SFP unit 12a or 12b.

  In the third optical transmission apparatus, the SERDES unit 9 combines the data so as to use any one of the two optical transmission lines 11a and 11b, and the SERDES unit 13 The same data is synthesized. Depending on the usage status of the optical transmission path, the SFP section that is not in use can be suspended to save power.

[Effect of the embodiment]
According to the present optical transmission device, since the transmission processing capability of the SFP unit 10 is within the range and allocated to each operator data while changing the compression rate, the data can be compressed and decompressed for each operator. The optical transmission capacity can be reduced while satisfying the characteristic signal standards.

  In the above, data is differentiated for each operator and the compression rate / expansion rate is changed. However, not only for each operator but also for the same company, if the communication method and frequency band used are different. Each data may be handled in the same manner as the data handling of the operators A to D.

  In the synthesis / separation circuits (SERDES units) 9 and 13, it is described that parallel is converted into serial data and synthesized, and serial data is converted into parallel data and separated. -Realization means by separation may be used.

  INDUSTRIAL APPLICABILITY The present invention is suitable for an optical transmission apparatus that can reduce optical transmission capacity while satisfying signal standards when optical transmission is performed for multi-frequency sharing.

  1-A to D ... base station, 2-A to D ... downlink input / uplink output unit, 3-A to D ... duplexer (DUP), 4-A to D ... RF / IF conversion unit, 5-A to D ... A / D conversion unit, 6-A to D ... IF / RF conversion unit, 7-A to D ... D / A conversion unit, 8. .. Signal processing unit, 9 ... Synthesize / separate circuit (SERDES unit), 10 ... Optical transceiver unit (SFP unit), 11 ... Optical transmission path, 12 ... Optical transceiver unit (SFP unit), 13 ... synthesis separation circuit (SERDES section), 14 ... signal processing section, 15-A to D ... D / A conversion section, 16-A to D ... IF / RF conversion section, 17- A to D ... A / D converter, 18-A to D ... RF / IF converter, 19-A to D ... Duplexer (DUP), 20-A to D ... Downlink output / uplink input section

Claims (4)

An optical transmission device that synthesizes signals of different frequency bands from a plurality of wireless communication units and transmits them using an optical transmission line,
A first optical transceiver module that is connected to the optical transmission line, converts an electrical signal into an optical signal, and outputs the optical signal to the optical transmission line;
A table for storing a compression rate of data satisfying a signal standard of an RF characteristic of each wireless communication unit for each wireless communication unit; and processing a signal from the plurality of wireless communication units; and the first optical transceiver A first signal processing unit that assigns a compression rate for a signal from each wireless communication unit within a range of processing capability in the module in place of the compression rate stored in the table, and compresses the signal according to the compression rate;
An optical transmission apparatus comprising: a first conversion unit configured to synthesize a signal for each wireless communication unit compressed by the first signal processing unit and output the synthesized signal to the first optical transceiver module.   2. The optical transmission apparatus according to claim 1, wherein the first signal processing unit changes the compression rate set in the table in accordance with a state of data input from the wireless communication unit. A second optical transceiver module for inputting an optical signal from the optical transmission line and converting it into an electrical signal;
A second converter for separating an electrical signal from the second optical transceiver module for each wireless communication unit;
The optical transmission device according to claim 1, further comprising: a second signal processing unit that decompresses a signal from the second conversion unit at a decompression rate corresponding to a compression rate for each wireless communication unit. . The second signal processing unit compresses signals from a plurality of wireless communication units at a compression rate for each wireless communication unit,
The second conversion unit synthesizes the signal for each wireless communication unit compressed by the second signal processing unit,
4. The optical transmission device according to claim 3, wherein the second optical transceiver module converts an electrical signal from the second conversion unit into an optical signal and outputs the optical signal to an optical transmission line.

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