JP7397234B2 - Optical transmission system and optical transmission method - Google Patents

Description

The present invention relates to an optical transmission system, which flexibly supports signal transmission of various carriers, frequency bands, and bandwidths without changing firmware, etc., improves convenience, and allows construction of various wireless areas. The present invention relates to an optical transmission system and an optical transmission method that can achieve the following.

[Description of prior art: Figure 10]
Recently, in mobile communications, signals in multiple frequency bands and multiple bandwidths are transmitted using multi-frequency waves, carrier aggregation, multiple antennas, etc. for high-speed, large-capacity communications.
Some of such mobile communication systems use optical transmission systems.

A conventional digital optical transmission system (simply referred to as an optical transmission system) will be explained using FIG. 10. FIG. 10 is an explanatory diagram showing the configuration of a conventional optical transmission system.
As shown in FIG. 10, the conventional optical transmission system includes a master station 1, a plurality of slave stations 2, and an optical fiber 3 that connects the master station 1 and each slave station 2, respectively.

The master station 1 includes a set of ADC (Analog to Digital Converter) 11 and DAC (Digital to Analog Converter) 12 provided for each signal input/output destination, and a plurality of input terminals 17 and output terminals corresponding to the input/output destination. 18, an FPGA (Field Programmable Gate Array) 13, a control unit 14, and a plurality of optical transceivers 15 corresponding to each slave station 2.

Here, the set of ADC11 and DAC12 corresponds to the frequency band (frequency band) and bandwidth of each communication carrier. It is possible to transmit signals of various frequencies and bandwidths.

The ADC 11 converts an analog signal input from a corresponding input terminal 17 into a digital signal, and outputs the digital signal to the FPGA 13.
The DAC 12 converts the digital signal input from the FPGA 13 into an analog signal and outputs the analog signal to the output terminal 18.

The FPGA 13 maps signals input in parallel from the plurality of ADCs 11 to different time domains according to predetermined mapping information, and outputs the mapped signals to the plurality of optical transceivers 15 as serial signals.
Furthermore, the FPGA 13 separates serial signals input from the plurality of optical transceivers 15 into parallel signals based on predetermined mapping information, and outputs the parallel signals to the corresponding DACs 12 .

The optical transceiver 15 converts the electrical signal into an optical signal and transmits it to the slave station 2 via the optical fiber 3, and conversely converts the optical signal received from the optical fiber 3 into an electrical signal and outputs it to the FPGA 13. .

The slave station 2 includes a plurality of optical transceivers 25, an FPGA 23, a control section 24, a plurality of ADCs 21, a plurality of DACs, a BPF (Band Pass Filter) 27, and an input/output terminal 28.

The optical transceiver 25 is connected to the optical fiber 3, transmits and receives optical signals, and mutually converts electrical signals and optical signals.
The FPGA 23 converts the serial signal input from the optical transceiver 25 into a parallel signal based on predetermined mapping information, and outputs the parallel signal to the corresponding DAC 22.
Further, the FPGA 23 arranges parallel signals input from the plurality of ADCs 21 in different time domains according to predetermined mapping information, converts them into serial signals, and outputs the serial signals to the optical transceiver 25.

The BPF 27 passes only the corresponding frequency bands of signals input from the plurality of DACs 22 and outputs them to the input/output terminal 28 .
Further, the BPF 27 separates the signal input from the input/output terminal 28 into a plurality of frequency bands, and outputs the signals to the corresponding ADCs 21 .
The input/output terminal 28 is connected to an antenna or the like, and inputs and outputs wireless signals.

In conventional digital optical transmission systems, the ADC 11, DAC 12, and FPGA 13 in the master station 1 and the ADC 21, DAC 22, and FPGA 23 in the slave station 2 have an integral structure or are fixed in combination. In other words, the combination of signals to be transmitted was fixed.
Furthermore, mapping of frequency bands and bandwidths of radio signals in the FPGA 13 of the master station 1 and the FPGA 23 of the slave station 2 has been fixedly performed based on preset information.

[Related technology]
In addition, as a conventional technology related to an optical transmission system, there is JP-A-2014-187450 ``Optical Transmission Device'' (Patent Document 1).
Patent Document 1 discloses that when optical transmission is performed using multiple frequencies, the compression ratio for the signal from each wireless communication unit is changed and assigned within the processing capacity of the optical transceiver, thereby satisfying the signal standard. An optical transmission device that can reduce optical transmission capacity is described.

Japanese Patent Application Publication No. 2014-187450

However, in conventional optical transmission systems, the pattern of combinations of carriers, frequency bands, and bandwidths is fixed, and changing the combination of carriers, frequency bands, and bandwidths requires changing the firmware, etc. , which involves changing the entire system configuration.
Therefore, conventional optical transmission systems have the problem of being inconvenient because they cannot flexibly accommodate various combinations of communication carriers, frequency bands, and bandwidths.

Furthermore, in Patent Document 1, information on communication carriers, frequency bands, and bandwidths is stored in the unit, and mapping is performed based on the information stored in the inserted unit, making it possible to transmit a variety of signals. It is not stated that.

The present invention has been made in view of the above-mentioned circumstances, and improves convenience by flexibly responding to various combinations of carriers, frequency bands, and bandwidths without making large-scale changes to the system. An object of the present invention is to provide an optical transmission system and an optical transmission method that can construct a variety of wireless areas.

The present invention to solve the problems of the conventional example described above is an optical transmission system that transmits digital signals between a master station and a slave station via an optical transmission line, in which the master station and a plurality of transmitting/receiving units each having a storage section that stores frequency information for mapping digital signals in accordance with the bandwidth ; It has a signal processing section that maps to the area and a control section that instructs mapping information to the signal processing section, the signal processing section and the control section are provided in the unit storage section, and the transmitting and receiving unit is removably attached to the unit storage section. The control unit reads frequency information from the storage unit, generates mapping information, and instructs the signal processing unit to use the mapping information.

Further, in the above-mentioned optical transmission system, the present invention provides an AD that is provided in the transmitting/receiving unit, a signal input terminal, a signal output terminal, and between the input terminal and the unit storage section, and that converts an analog signal into a digital signal. The present invention is characterized in that it includes a converting section and a DA converting section that is provided between the output terminal and the unit storage section and converts a digital signal into an analog signal.

Further, in the optical transmission system of the present invention, the unit storage section of the master station is capable of inserting a plurality of transmitting/receiving units that store frequency information that specifies communication carriers, frequency bands, and frequency widths, and controls The unit is characterized in that the mapping information is generated based on frequency information stored in a transmitting/receiving unit inserted into the unit storage unit among the plurality of transmitting/receiving units.

Further, in the present invention, the master station inquires of the slave station about the mapping information held by the slave station, and when the mapping information matches the mapping information stored in the storage section of the transmitting/receiving unit of the master station, transmits the digital signal. It is characterized by doing.

The present invention also provides an optical transmission method for transmitting digital signals in a plurality of frequency bands and a specific bandwidth between a master station and a slave station via an optical transmission line, wherein the master station is inserted into a unit housing part. reads frequency information for mapping digital signals based on the carrier's frequency band and bandwidth from the storage unit in the transmitted/receiver unit, generates mapping information, and transmits digital signals based on the mapping information. It is characterized in that it is mapped onto the data area of the signal and transmitted to the slave station via an optical transmission line.

According to the present invention, there is provided an optical transmission system that transmits digital signals between a master station and a slave station via an optical transmission line, and the master station transmits digital signals according to carriers, frequency bands, and bandwidths. a plurality of transmitting/receiving units each having a storage section that stores frequency information for performing mapping; a signal processing section that maps digital signals from the plurality of transmitting /receiving units to a data region of a transmission signal according to instructed mapping information; a control section that instructs mapping information to the signal processing section, the signal processing section and the control section are provided in the unit storage section, the transmitting/receiving unit is removably housed in the unit storage section, and the control section is installed in the storage section. Since the optical transmission system reads frequency information from the network, generates mapping information, and instructs the signal processing unit to use the mapping information, the transmitting/receiving unit corresponding to the carrier, frequency band, and bandwidth can be used depending on the desired communication service. Mapping information can be easily generated by inserting the This has the effect of building a wireless area.

Further, according to the present invention, the master station inquires of the slave station about the mapping information held by the slave station, and when the mapping information matches the mapping information stored in the storage section of the transmitting/receiving unit of the master station, the master station transmits the digital signal. Since the above-mentioned optical transmission system performs transmission, there is an effect that the transmission between the master station and the slave station can be performed reliably.

Further, according to the present invention, there is provided an optical transmission method for transmitting digital signals in a plurality of frequency bands and a specific bandwidth between a master station and a slave station via an optical transmission path, wherein the master station has a unit housing. Frequency information for mapping digital signals based on the frequency band and bandwidth of the carrier is read from the storage section in the transmitting/receiving unit inserted in the transmitter/receiver unit to generate mapping information, and the digital signal is generated based on the mapping information. This optical transmission method maps the information into the data area of the transmission signal and transmits it to the slave station via the optical transmission line, so mapping information can be generated according to the inserted transceiver unit without changing the entire system. This has the advantage of being able to flexibly support a variety of carriers, frequency bands, and bandwidths, improving convenience, and allowing the construction of various wireless areas.

FIG. 2 is an explanatory diagram showing the configuration of the present optical transmission system. FIG. 2 is an explanatory diagram showing frequency bands and bandwidths for each communication carrier. FIG. 3 is an explanatory diagram showing a selection example (1) of frequency bands and selection widths. It is an explanatory view showing example (2) of selection of a frequency band and a bandwidth. FIG. 2 is an explanatory diagram showing generation of frequency array information in a master station. It is an explanatory diagram showing example (1) of digital data mapping. It is an explanatory diagram showing digital data mapping (2). FIG. 3 is an explanatory diagram showing control (1) for the slave station 200. FIG. It is an explanatory diagram showing control (2) for a slave station. FIG. 1 is an explanatory diagram showing the configuration of a conventional optical transmission system.

Embodiments of the present invention will be described with reference to the drawings.
[Overview of embodiment]
The optical transmission system according to the embodiment of the present invention (this optical transmission system) stores frequency information for mapping digital signals in correspondence with communication carriers, frequency bands, and bandwidths in the unit storage section of the master station. A plurality of transmitting/receiving units for storage are removably housed, and a control section reads frequency information from the storage section of the transmitting/receiving unit inserted into the unit housing section, generates mapping information, and outputs it to the signal processing section for signal processing. The unit maps digital signals from multiple transmitting/receiving units based on the mapping information, and each transmitting/receiving unit stores frequency information that specifies the carrier, frequency band, and bandwidth, and transmits the desired signal. Mapping information can be easily generated by inserting transmitting/receiving units according to the communication service, and it is possible to flexibly support a variety of communication carriers, frequency bands, and bandwidths without making major changes to the entire system. It is something that can be done.

In addition, in this optical transmission system, the master station inquires of the slave station about the mapping information held by the slave station, and if the mapping information matches the mapping information stored in the storage unit of the transmitter/receiver unit of the master station, the digital signal is transmitted. and if they do not match, the mapping information of the slave station is controlled to match the mapping information of the master station, ensuring reliable transmission between the master station and the slave station. .
Further, the optical transmission method according to the embodiment of the present invention is an optical transmission method in the present optical transmission system.

[Configuration of this optical transmission system: Figure 1]
The configuration of this optical transmission system will be explained using FIG. 1. FIG. 1 is an explanatory diagram showing the configuration of this optical transmission system. Note that the same parts as in the conventional optical transmission system shown in FIG. 10 are denoted by the same reference numerals, and a description thereof will be omitted.
As shown in FIG. 1, this optical transmission system includes a wireless transmitting/receiving unit accommodating section 100, and a plurality of wireless transmitting/receiving units 101-1 to 101-n (only one is shown, and when not distinguishing between them, the wireless transmitting/receiving unit 101 The main station 10 includes a master station 10 and a plurality of slave stations 200, and an optical fiber 3 that connects the master station 10 and each slave station 200.
Note that a relay station may be provided between the master station 10 and the slave station 200, and optical transmission may be performed via the relay station.

The features of this optical transmission system will be explained.
The wireless transmitting/receiving unit accommodating section 100 of the master station 10 includes an FPGA 113, a control section 114, a plurality of optical transceivers 15, and a connection board (BB) 117 inside, and has a plurality of wireless transmitting/receiving units 101 outside. An insertable insertion section is formed to accommodate the inserted wireless transmitting/receiving unit 101.
Electrodes and wiring for connecting the wireless transmission/reception unit 101 and the connection board 117 are formed in the insertion portion.

The wireless transmitting/receiving unit 101 is a characteristic part of this optical transmission system, and a plurality of wireless transmitting/receiving units 101 are provided corresponding to combinations of communication carriers, frequency bands, and bandwidths.
Each wireless transmission/reception unit 101 includes an ADC 11, a DAC 12, an input terminal 17, an output terminal 18, and a frequency information storage section (denoted as Band Info in the figure) 116.

The ADC 11 converts an analog signal input from the input terminal 17 into a digital signal and outputs the digital signal to the connection board 117, as in the conventional case.
The DAC 12 converts the digital signal input from the connection board 117 into an analog signal and outputs it to the output terminal 18.

The frequency information storage unit 116 stores frequency information including communication carriers, frequency bands, and bandwidths. Frequency information will be described later.
In this optical transmission system, individual wireless transmitting/receiving units 101 are prepared in accordance with the combinations of carriers, frequency bands, and bandwidths, and the necessary wireless transmitting/receiving units 101 are installed according to the desired communication service. By selecting and inserting it into the wireless transmitting/receiving unit accommodating section 100, it is possible to map various signals in the FPGA 113 of the master station 10, thereby realizing the communication service.

Note that inserting the wireless transmitting/receiving unit 101 may mean actually inserting the wireless transmitting/receiving unit 101 into an insertion section (slot), or if multiple wireless transmitting/receiving units 101 are inserted in advance and connected to the connection board 117 by a switch. It is also possible to set the connection state to "connected".

The connection board 117 is a board into which the wireless transmitting/receiving unit 101 is inserted when the wireless transmitting/receiving unit 101 is inserted into the insertion part of the wireless transmitting/receiving unit accommodating part 100, and connects each wireless transmitting/receiving unit 101 and the inside of the wireless transmitting/receiving unit accommodating part 100. The FPGA 113 and the control unit 114 are connected to each other.

The control unit 114 is a characteristic part of this optical transmission system, and reads frequency information from the frequency information storage unit 116 of the plurality of inserted wireless transmitting/receiving units 101, adds it, and stores the mapping information of the master station 10 (master station mapping information). ) is generated and output to the FPGA 113.

Further, as described later, the control unit 114 requests the child station 200 for mapping information (slave station mapping information) stored in the child station 200, and checks whether it matches the master station mapping information. Then, only when they match, signal transmission with the slave station 200 is performed.
If the slave station mapping information is different from the master station mapping information, the slave station 200 is controlled to modify the slave station mapping information.
The operation of the control unit 114 will be described later.

The FPGA 113 corresponds to a signal processing unit described in the claims, and maps signals input in parallel from the plurality of wireless transmitting/receiving units 101 to different time axes according to master station mapping information instructed by the control unit 114. , and output to a plurality of optical transceivers 15.
Similarly, the FPGA 113 separates the mapped signals input from the plurality of optical transceivers 15 based on the master station mapping information, and outputs the separated signals to the plurality of wireless transmission/reception units 101.

In this optical transmission system, although the mapping processing and its inverse processing in the FPGA 113 are the same as in the past, the mapping information used for processing is not fixed, but is mapped to the mapping information generated by the control unit 114 according to the wireless transceiver unit 101 to be inserted. Use station mapping information.
As a result, this optical transmission system enables mapping according to signals of various systems and realizes various wireless communication services.
Further, the FPGA 113 configures (sets) digital filters corresponding to multiple types of bandwidths/antennas according to information read from the frequency information section 116 of the wireless transmitting/receiving unit 101.

The basic configuration of the slave station 200 is the same as the conventional one, but it includes a frequency information storage section 226 that stores slave station mapping information, and the operations of the control section 224 and FPGA 223 are partially different from the conventional one.

The frequency information storage unit 226 stores slave station mapping information used in mapping processing in the FPGA 223 of the slave station 200.
As a feature of this optical transmission system, if the preset slave station mapping information differs from the master station mapping information of the master station 10, it is rewritten by the control unit 224.

When the control unit 224 receives an instruction to rewrite the slave station mapping information from the master station 10, it rewrites and updates the slave station mapping information in the frequency information storage unit 226, and transfers the updated slave station mapping information to the FPGA 223. Output to.

The FPGA 223 performs processing of parallel-to-serial conversion or serial-to-parallel conversion between the plurality of ADCs 21 and DACs 22 and the optical transceiver 22 as in the past, but it also performs slave station mapping used for mapping processing and its inverse processing. The information is not fixed, but information stored in the frequency information storage section 226 is used.

In the slave station 200, the FPGA 223 separates the signal received by the optical transceiver 25 into a plurality of carrier/communication band/total bandwidth pairs based on the slave station mapping information instructed by the control unit 224. The signals are outputted to the corresponding DACs 22, and then outputted to an antenna or the like via the BPF 27 and the input/output terminal 28.

[Communication carrier frequency bands and bandwidth: Figure 2]
Next, frequency bands and bandwidths for each communication carrier will be explained using FIG. 2. FIG. 2 is an explanatory diagram showing frequency bands and bandwidths for each carrier, where (a) corresponds to carrier X, (b) corresponds to carrier Y, and (c) corresponds to carrier Z. ing.
The transmission capacity between the master station 10 and the slave station 200 is determined by the bandwidth, and is limited by the optical transceivers 15 and 25 that serially transmit a plurality of digital wireless signals.

As shown in FIG. 2, the communication carrier, frequency band, bandwidth/number of antennas, number of antennas, and total bandwidth are defined for signals transmitted by this optical transmission system. In this embodiment, the combination of communication carrier, frequency band, and total bandwidth is referred to as frequency information.
For example, as shown in FIG. 2(a), in frequency band F1, communication carrier width/number of antennas) x number of antennas). Here, "B" is a reference value of bandwidth, and the total bandwidth that can be transmitted by the optical transceivers 15 and 25 is B×100.
Note that the antenna indicates a transmission path compatible with multiple antennas such as MIMO (Multiple-Input and Multiple-Output).

In this optical transmission system, the frequency information section 116 of the wireless transmitting/receiving unit 101 stores all the frequency information shown in FIG. - Information in which frequency bands and bandwidths (total bandwidth) are combined on a one-to-one basis, that is, information for one row of each table in FIG. 2 has been specified (selected).

[Example of frequency band and bandwidth selection (1): Figure 3]
Next, an example (1) arbitrarily selected from among the above-mentioned combinations of carriers, frequency bands, and bandwidths will be described using FIG. 3. FIG. 3 is an explanatory diagram showing a selection example (1) of frequency bands and selection widths.
As shown in FIG. 3, in this example, it is assumed that signals of only communication carrier X are transmitted, and the selected frequency band of communication carrier This is achieved by inserting the wireless transmitting/receiving unit 101 for which the frequency information corresponding to is specified into the wireless transmitting/receiving unit accommodating section 100.
In this example, seven wireless transmitting/receiving units 101 corresponding to frequency bands are inserted.

Then, the control section 114 integrates the information of the plurality of radio transmitting/receiving units 101 to generate master station mapping information showing the contents of FIG. 3, and outputs it to the FPGA 113 for mapping processing.
The total bandwidth that can be transmitted in this optical transmission system is B×100, but in the example of FIG. 3, the total bandwidth is B×63.5. In this way, if the total bandwidth is less than the upper limit of the transmission capacity, the data is filled with fixed data such as "0" and transmitted.

[Example of frequency band and bandwidth selection (2): Figure 4]
FIG. 4 is an explanatory diagram showing an example (2) of selecting frequency bands and bandwidths.
In the example of FIG. 4, it is assumed that signals of communication carriers X, Y, and Z are transmitted, and the selected communication carrier, frequency band, and total bandwidth are selected from the wireless transmitting/receiving unit 101 that stores the information in FIG. This is achieved by inserting a plurality of (12 units in this case) units for which frequency information corresponding to is specified into the wireless transmitting/receiving unit accommodating section 100.
The sum of the total bandwidths in FIG. 4 matches B×100, which is the upper limit of the transmittable bandwidth.

[Example of frequency array information at the master station: Figure 5]
Next, an example of frequency arrangement information in the master station will be explained using FIG. 5. FIG. 5 is an explanatory diagram showing generation of frequency arrangement information in the master station.
The frequency array information of the master station is array information that specifies the master station mapping information used by the FPGA 113.

A plurality of (N in this case) wireless transmitting/receiving units 101 can be inserted into the wireless transmitting/receiving unit accommodating section 100 . Here, the number of wireless transmitting/receiving units 101 corresponds to the number of assumed communication carrier/frequency band/total bandwidth pairs (frequency information), and for example, the number of frequency information shown in FIG. It is assumed that they match.
The frequency information storage section 116 of each radio transmitting/receiving unit 101 stores all the frequency information shown in FIG. 1 line) is selected and specified.

When specifying frequency information, for example, the wireless transmitting/receiving unit 101 is provided with dip switches that correspond one-to-one to N pieces of frequency information, and by setting one of the switches to ON, the corresponding one can be specified. A set of frequency information is identified.
FIG. 5 shows which of the N dip switches is turned on in each wireless transmitting/receiving unit 101, as well as information on the communication carrier, frequency band, and total bandwidth identified thereby. There is.

In the example of FIG. 5, the first switch of the wireless transmitting/receiving unit (1) is turned ON, information on carrier X, frequency band F1, and total bandwidth B×2 is specified, and the wireless transmitting/receiving unit (2 ), the second switch is turned on, and the information on carrier Y, frequency band F1, and total bandwidth B x 2 is specified. Thus, information on communication carrier X, frequency band F10, and total bandwidth B×5 is specified.

The on/off information of the dip switch is N-bit information for each wireless transmitting/receiving unit 101.
For example, the switch information indicating the on/off state of the switch of the wireless transmitting/receiving unit (1) is "000...001", and the switch information of the wireless transmitting/receiving unit (2) is "000...010".

The control section 114 of the base device 10 detects whether each wireless transmitting/receiving unit 101 is inserted into the wireless transmitting/receiving unit housing section 100. The presence or absence of insertion is detected, for example, by determining the insertion position of each wireless transmitting/receiving unit 101 and detecting whether or not a signal is input from the connection board 117.
In the example of FIG. 5, the wireless transmitting/receiving unit (1) is inserted (with insertion), the wireless transmitting/receiving unit (2) is not inserted (with no insertion), the wireless transmitting/receiving unit (3) is inserted (with insertion), . . . wireless The transmission and reception unit (N-2) is detected as inserted, the wireless transmission and reception unit (N-1) is not inserted, and the wireless transmission and reception unit (N) is detected as inserted.

Then, the control unit 114 of the master station 10 adds the N-bit switch information of the inserted radio transmitting/receiving unit 101 to obtain N-bit information indicating the switch status of the entire master station 10, as shown in FIG. (master station implementation information, master station arrangement information).
As shown in Figure 5, depending on the bit set to ``1'' by the master station implementation information, multiple ``communication carriers, communication bands, total A set of "bandwidths" is specified.

Information indicating the set of "communication carrier, communication band, and total bandwidth" to be transmitted is referred to as master station mapping information, and the control unit 114 outputs (instructs) the master station mapping information to the FPGA 113, and the FPGA 113 The input data is mapped based on the input (instructed) master station mapping information.

In this way, in this optical transmission system, the frequency information that specifies the set of "communication carrier, communication band, total bandwidth" is stored in a one-to-one correspondence with the wireless transmitting/receiving unit 101, and the desired information is stored. A desired transmission system can be realized by inserting an appropriate wireless transmission/reception unit 101 into the wireless transmission/reception unit accommodating section 100 according to the transmission system.

In particular, in this optical transmission system, by performing settings on the wireless transmitting/receiving unit in advance, detailed settings are not required at the site where the master station 10 is installed, and necessary wireless transmitting/receiving units 101 are installed in the wireless transmitting/receiving unit housing section 100. This greatly simplifies the installation process, as it only needs to be inserted into the holder.

[Example of digital data mapping (1): Figure 6]
Next, an example of digital data mapping in the FPGA 113 will be described using FIG. 6. FIG. 6 is an explanatory diagram showing an example (1) of digital data mapping.
As shown in FIG. 6, the transmission signal is divided into a control signal area (C-Plane) and a data area (U-Plane). A digital signal input from the ADC 11 of the wireless transmitting/receiving unit 101 is mapped to a data area.

The mapping shown in FIG. 6 is based on the master station mapping information shown in FIG. 3 (shown at the bottom left of FIG. 6), and data of communication carrier X is mapped.
Furthermore, as described above, if there is free space in the transmission capacity, fixed data such as "0" is placed.
The control signal area includes N-bit master station arrangement information generated by the control unit 114 and the like.
The FPGA 113 then outputs the mapped transmission data to the optical transceiver 15.

Furthermore, the FPGA 113 separates the serial data received from the optical transceiver 15 into a plurality of carrier/communication band/total bandwidth sets based on the master station mapping information, and transmits the serial data to the corresponding wireless transmitting/receiving unit 101. Output to DAC12.

[Example of digital data mapping (2): Figure 7]
Another example of digital data mapping in the FPGA 113 will be described using FIG. 7. FIG. 7 is an explanatory diagram showing digital data mapping (2).
FIG. 7 is based on the master station mapping information shown in FIG. 4, and maps data of communication carriers X, Y, and Z.
In this example, the total bandwidth based on the master station mapping information is B×100, which matches the maximum transmission capacity.

[Slave station mapping information]
In this optical transmission system, the master station 10 monitors the mapping information of the slave station 200, and performs transmission if the mapping information of the master station 10 and slave station 200 match, and does not transmit if they do not match.

In the slave station 200, the frequency information storage unit 226 stores slave station mapping information.
The slave station mapping information is basically set in advance with the slave station mapping information and array information that specifies it so that it matches the master station mapping information, but the master station mapping information may be changed on the master station 10 side. If a wrong slave station device is connected, etc., the master station 10 performs control to correct the slave station mapping information.
Note that there are multiple types of slave stations 200, and the stored slave station mapping information differs depending on the type.

[Control over slave station (1): Figure 8]
An example of control over the slave station 200 will be explained using FIG. 8. FIG. 8 is an explanatory diagram showing control (1) for the slave station 200.
As shown in FIG. 8, the control unit 114 of the master station 10 stores "1100...0011" as array information that specifies the master station mapping information.
The frequency information storage section 226 of the slave station 200 (type 1) stores "1100...0011" as array information.
As described above, the array information and the mapping information have a one-to-one correspondence.

In this optical transmission system, at the start of operation or periodically, the control unit 114 of the master station 10 requests array information from each slave station 200 connected to the master station 10.
When receiving the request from the master station 10, the control unit 224 of the slave station 200 reads out the array information stored in its own frequency information storage unit 226 and responds to the master station 10 (array information response).
The control unit 114 of the master station 10 compares the stored array information of the master station 10 and the array information received from the slave station 200, and extracts the difference by comparing bit by bit.

If the difference is 0 (all bits match), the master station 10 instructs the slave station 200 to make the currently set array information "1100...0011" valid, The control unit 224 of the slave station 200 validates the array information accordingly, and outputs slave station mapping information corresponding to the array information to the FPGA 223.
In this way, it is confirmed that the mapping information of the master station 10 and the slave station 200 match, and transmission between the master station 10 and the slave station 200 is performed normally.

[Control over slave station (2): Figure 9]
Another control for the slave station will be explained using FIG. 9. FIG. 9 is an explanatory diagram showing control (2) for the slave station.
The control unit 114 of the master station 10 compares the array information of the master station 10 with the array information received from the slave station 200, and if any of the bits is different, the controller 114 does not perform transmission.
Then, information indicating the different bits is transmitted, and control is performed to invert the bits.

The example in FIG. 9 shows a case where the array information of the master station 10 is "1000...0011" and the array information of the slave station 200 is "1100...0011". , transmits "0100...0000" indicating bits that are different between the master station and the slave station, and instructs to invert the bits. In the figure, it is written as "0100...0000 invalidated".

As a result, the control section 224 of the slave station 200 inverts the different bit from "1" to "0" and stores it in the frequency information storage section 226, and the array information of the slave station becomes "1000...0011". This matches the arrangement information of the master station 10.
In this case, since the arrangement information of the master station 10 and the slave station 200 match, transmission between the master station 10 and the slave station 200 is possible.
In this way, even if the arrangement information of the master station 10 changes, there is no need to prepare and reconnect another slave station 200, and the system can be easily modified.

Furthermore, if the array information of the slave station 200 is different from the array information of the master station 10, the control unit 114 of the master station 10 displays a display unit (not shown) indicating that the identification information of the slave station 200 and the array information do not match. An alarm is displayed indicating this, and an alert signal is issued to notify the outside.

An alarm display or an alert may be issued when the degree of difference in the array information is large, for example, when the number of bits that do not match the array information of the master station 10 is greater than or equal to a specific number.
In addition, abnormalities such as when a slave station device other than the slave station 200 that should be connected is connected due to an incorrect connection, or when the frequency band and bandwidth configuration of the slave station 200 do not match the master station at all. An alarm is also issued in the same way.
Similarly, when the slave station 200 receives control information indicating that the arrangement information is different from the master station 10, the slave station 200 may also perform a display such as blinking a lamp.

[Effects of embodiment]
According to this optical transmission system, the wireless transmitting/receiving unit storage unit 100 of the master station 10 includes a plurality of wireless transmitting/receiving units that store frequency information for mapping digital signals in correspondence with carriers, frequency bands, and bandwidths. 101 is removably housed, and the control unit 114 reads frequency information from the frequency information storage unit 116 of the wireless transmitting/receiving unit 101 inserted in the wireless transmitting/receiving unit accommodating unit 100, generates mapping information, and outputs it to the FPGA 113. The FPGA 113 maps digital signals from a plurality of wireless transmitting/receiving units 101 based on the mapping information, and each wireless transmitting/receiving unit 101 stores frequency information that specifies the carrier, frequency band, and bandwidth. mapping information can be easily generated by inserting the wireless transmitting/receiving unit 101 according to the desired communication service. This has the effect of being able to respond flexibly.

In the present embodiment, the control unit 114 of the master station 10 generates the master station mapping information based on the frequency information of the wireless transmitting/receiving unit 101, but this processing may also be performed by the FPGA 113. good.

This application claims priority benefit based on Japanese Patent Application No. 2021-047702 filed on March 22, 2021, and the entire disclosure thereof is incorporated herein by reference.

The present invention can flexibly support various combinations of carriers, frequency bands, and bandwidths, improve convenience, and create a variety of wireless areas without making large-scale changes to the system. Suitable for optical transmission systems and optical transmission methods.

1, 10... Master station, 2,200... Slave station, 3... Optical fiber, 11, 21... ADC, 12, 22... DAC, 13, 23, 113, 223... FPGA, 14, 24, 114, 224... Control 15, 25... Optical transceiver, 17... Input terminal, 18... Output terminal, 27... BPF, 28... Input/output terminal, 100... Wireless transmitting/receiving unit housing section, 101... Wireless transmitting/receiving unit, 116, 226... Frequency information storage Part, 117...Connection board

Claims (5)

An optical transmission system that transmits digital signals between a master station and a slave station via an optical transmission line,
The said master station is
a plurality of transmitting/receiving units each having a storage unit that stores frequency information for mapping digital signals in correspondence with communication carriers, frequency bands, and bandwidths;
a signal processing unit that maps digital signals from the plurality of transmitting and receiving units to a data region of a transmission signal according to instructed mapping information;
a control unit that instructs the signal processing unit to send the mapping information;
The signal processing section and the control section are provided in a unit storage section,
The transmitting/receiving unit is removably housed in the unit housing,
An optical transmission system, wherein the control unit reads the frequency information from the storage unit to generate the mapping information, and instructs the signal processing unit to use the mapping information. The transmitting/receiving unit includes a signal input terminal, a signal output terminal, an AD conversion section that is provided between the input terminal and the unit storage section and converts an analog signal into a digital signal, and a signal input terminal and the signal output terminal. 2. The optical transmission system according to claim 1, further comprising: a DA converter that is provided between the unit storage section and converts a digital signal into an analog signal. The unit storage section of the master station can insert a plurality of transmitting/receiving units that store frequency information that specifies communication carriers, frequency bands , and frequency widths. 2. The optical transmission system according to claim 1, wherein the mapping information is generated based on frequency information stored in a transmitting/receiving unit inserted into the unit storage section. The master station inquires of the slave station about the mapping information held by the slave station, and when the mapping information matches the mapping information stored in the storage unit of the transmission/reception unit of the master station, transmits the digital signal. The optical transmission system according to claim 1. An optical transmission method for transmitting digital signals between a master station and a slave station using an optical transmission path in multiple frequency bands with a specific bandwidth, the method comprising:
The master station generates mapping information by reading frequency information for mapping digital signals based on a frequency band and bandwidth of a communication carrier from a storage section in a transmitting/receiving unit inserted in a unit storage section; An optical transmission method, comprising mapping a digital signal to a data area of a transmission signal based on the mapping information, and transmitting the digital signal to the slave station via the optical transmission path.

Images