JP7027681B2 - Transmitter, receiver and communication method - Google Patents

Description

The present invention relates to communication control, and more particularly to the setting of communication parameters.

An optical communication system using an optical fiber capable of transmitting a large amount of data at high speed has become widely used. With widespread use, the stability of data communication has become important, and there is an increasing demand for maintaining transmission quality and communication continuity in optical communication systems. In an optical communication system using an optical fiber, a large amount of data is often communicated over a long distance. Therefore, it is desirable to be able to simplify work such as setting of communication devices installed at remote locations and establish communication.

Further, in the optical communication system, various modulation methods are used in order to communicate a large amount of data over a long distance. As the modulation method in the optical communication system, for example, BPSK (Binary Phase Shift Keying) and QPSK (Quadrature Phase Shift Keying) are used. Further, a modulation method such as 8QAM (Quadrature Amplitude Modulation) or 16QAM may be used.

In order to establish communication between the communication device on the transmitting side and the communication device on the receiving side, it is necessary to set various communication parameters to be the same in the communication device on the transmitting side and the receiving side in addition to the modulation method. Further, in order to stably perform high-speed and large-capacity communication, it is necessary to set the optimum communication parameters. As communication parameters in the optical communication system, in addition to the modulation method, communication parameters such as a transmission rate, a frame format, and an error correction method are set.

When a worker sets each communication parameter in the communication device on the transmitting side and the receiving side, the worker needs to recognize various communication parameters corresponding to each communication device constituting the optical communication system. .. Further, if the communication is not established or the transmission quality is low in the communication parameters set by the operator, it is necessary to adjust the communication parameters. Therefore, setting the communication parameters of the optical communication system may be a complicated and time-consuming task. Therefore, it is desirable to be able to easily set the optimum communication parameters and establish communication when changing, adding, or maintaining the communication device. Therefore, a technique for automatically setting communication parameters of each communication device in a communication system is being developed. As a technique for automatically setting communication parameters of each communication device in such a communication system, for example, a technique such as Patent Document 1 is disclosed.

Patent Document 1 relates to a transmission system including a transmission device having a plurality of error correction circuits. In the transmission system of Patent Document 1, the transmission device on the receiving side monitors the signal quality. The transmission device on the receiving side selects an error correction method according to the signal quality, and notifies the transmission device on the transmitting side of the information of the selected error correction method. Further, the transmission device on the transmitting side that has received the notification of the error correction method notifies the transmission device on the receiving side of the timing of switching the error correction circuit. The transmission device on the transmitting side and the transmission device on the receiving side switch each error correction circuit at the timing notified by the transmission device on the transmitting side. Patent Document 1 states that such a configuration enables high error correction processing by flexibly adapting to transmission line characteristics and the like.

Japanese Unexamined Patent Publication No. 2010-278974

However, the technique of Patent Document 1 is not sufficient in the following points. The transmission system of Patent Document 1 monitors the signal quality in the transmission device on the receiving side, and notifies the transmission device on the transmitting side of the information of the error correction method selected based on the monitoring result. Therefore, the transmission system of Patent Document 1 needs to transmit and receive a sufficient amount of signals in order to judge the signal quality when changing the error correction method as a communication parameter. Therefore, in Patent Document 1, it is not possible to select the optimum parameter when establishing communication. Therefore, the technique of Patent Document 1 is not sufficient as a technique for easily setting the optimum communication parameter and establishing communication.

In order to solve the above problems, it is an object of the present invention to obtain a transmitting device, a receiving device and a communication method capable of easily setting optimum communication parameters and establishing communication.

In order to solve the above problems, the transmission device of the present invention includes a signal transmission means, a parameter transmission means, and a transmission control means. The signal transmitting means transmits an optical signal via a transmission line. The parameter transmitting means transmits the information of the second communication parameter via the transmission path when the signal transmitting means transmits the optical signal based on the first communication parameter. The transmission control means controls the signal transmission means to transmit based on the second communication parameter after transmitting the information of the second communication parameter.

The receiving device of the present invention includes a signal receiving means, a parameter detecting means, and a receiving control means. The signal receiving means receives an optical signal via a transmission line. The parameter detecting means detects the information of the second communication parameter included in the received optical signal based on the communication parameter of the first setting. The reception control means controls the signal receiving means to receive the optical signal based on the second communication parameter when the parameter detecting means detects the information of the second communication parameter.

In the communication method of the present invention, when an optical signal is transmitted via a transmission line based on the first communication parameter, information on the second communication parameter is transmitted via the transmission line. In the communication method of the present invention, after transmitting the information of the second communication parameter, the optical signal is transmitted based on the second communication parameter.

According to the present invention, it is possible to easily set the optimum communication parameters and establish communication.

It is a figure which shows the outline of the structure of the 1st Embodiment of this invention. It is a figure which shows the outline of the structure of the 2nd Embodiment of this invention. It is a figure which shows the outline of the structure of the 3rd Embodiment of this invention. It is a figure which shows the structure of the transmission device of the 3rd Embodiment of this invention. It is a figure which shows the structure of the receiving apparatus of the 3rd Embodiment of this invention. It is a figure which shows the example of the communication parameter in the 3rd Embodiment of this invention. It is a figure which shows the outline of the structure of the 4th Embodiment of this invention. It is a figure which shows the structure of the transmission device of 4th Embodiment of this invention. It is a figure which shows a part of the structure of the transmission device of 4th Embodiment of this invention. It is a figure which shows the structure of the receiving apparatus of 4th Embodiment of this invention. It is a figure which shows the outline of the structure of the 5th Embodiment of this invention. It is a figure which shows the structure of the transmission device of the 5th Embodiment of this invention. It is a figure which shows the example of the frame structure in 5th Embodiment of this invention. It is a figure which shows the structure of the receiving apparatus of the 5th Embodiment of this invention. It is a figure which shows the outline of the structure of the 6th Embodiment of this invention. It is a figure which shows the structure of the communication apparatus of 6th Embodiment of this invention. It is a figure which shows the example of setting of the communication parameter in 6th Embodiment of this invention. It is a figure which shows the outline of the structure of the 7th Embodiment of this invention. It is a figure which shows the structure of the communication apparatus of 7th Embodiment of this invention.

(First Embodiment)
The first embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 shows an outline of the configuration of the transmission device of the present embodiment. The transmission device of the present embodiment includes a signal transmission means 1, a parameter transmission means 2, and a transmission control means 3. The signal transmitting means 1 transmits an optical signal via a transmission line. When the signal transmitting means 1 transmits an optical signal based on the first communication parameter, the parameter transmitting means 2 transmits the information of the second communication parameter via the transmission path. The transmission control means 3 controls the signal transmission means 1 to transmit the optical signal based on the second communication parameter after transmitting the information of the second communication parameter.

In the transmission device of the present embodiment, when the signal transmission means 1 transmits an optical signal via the transmission path based on the first communication parameter, the parameter transmission means 2 displays the information of the second communication parameter. It is transmitted via the transmission line. Therefore, by sharing the communication parameter information between the transmitting device and the communication device on the receiving side based on the information of the second communication parameter transmitted from the transmitting device, it is possible to automatically change the setting of the communication parameter. .. That is, by using the transmitting device of the present embodiment, information on the more optimal second communication parameter is shared between the transmitting device and the receiving device when operating with the first communication parameter such as the initial setting. You can change the settings to more optimal communication parameters. As a result, by using the transmission device of the present embodiment, it is possible to easily set the optimum communication parameters and establish communication.

(Second embodiment)
A second embodiment of the present invention will be described in detail with reference to the drawings. FIG. 2 shows an outline of the configuration of the receiving device of the present embodiment. The receiving device of the present embodiment includes a signal receiving means 6, a parameter detecting means 7, and a receiving control means 8. The signal receiving means 6 receives an optical signal via a transmission line. The parameter detecting means 7 detects the information of the second communication parameter included in the optical signal received based on the first communication parameter. The reception control means 8 controls the signal receiving means 6 to receive the optical signal based on the second communication parameter when the parameter detecting means 7 detects the information of the second communication parameter.

In the receiving device of the present embodiment, when the signal receiving means 6 receives the optical signal via the transmission line based on the first communication parameter, the parameter detecting means 7 receives the information of the second communication parameter. It is extracted from the optical signal sent via the transmission line. Therefore, the receiving device of the present embodiment can obtain the information of the second communication parameter from the communication device on the transmitting side. Based on the information of the second communication parameter transmitted from the communication device on the transmitting side, the communication parameter setting can be automatically changed by sharing the communication parameter information between the transmitting device and the communication device on the receiving side. can. That is, by using the receiving device of the present embodiment, when operating with the first communication parameter such as the initial setting, the information of the more optimum second communication parameter is shared between the transmitting device and the receiving device. You can change the settings to more optimal communication parameters. As a result, by using the receiving device of the present embodiment, it is possible to easily set the optimum communication parameters and establish the communication.

Further, a communication system can be configured by connecting the transmitting device of the first embodiment and the receiving device of the second embodiment via a transmission line. In the case of such a communication system, the parameter transmitting means 2 of the transmitting device transfers the information of the second communication parameter and the information of the second communication parameter based on the first communication parameter to the transmission line. Send to the receiver via. Further, the parameter detecting means 7 of the receiving device receives the information of the second communication parameter from the transmitting device via the transmission path when communicating based on the first communication parameter. By configuring the communication system in such a configuration, it is possible to easily set the optimum communication parameters and establish communication.

(Third embodiment)
A third embodiment of the present invention will be described in detail with reference to the drawings. FIG. 3 shows an outline of the configuration of the communication system of the present embodiment. The communication system of the present embodiment includes a transmitting device 10 and a receiving device 20. Further, the transmitting device 10 and the receiving device 20 are connected to each other via a transmission line 30. The communication system of the present embodiment is an optical communication network that transmits a client signal input to the transmitting device 10 to the receiving device 20 as an optical signal via a transmission line 30.

The configuration of the transmission device 10 will be described. FIG. 4 shows the configuration of the transmission device 10 of the present embodiment. The transmission device 10 includes an input port 11, a client signal reception unit 12, a line signal transmission unit 13, an electric light conversion unit 14, a combine wave unit 15, a transmission control unit 16, and a parameter transmission unit 17. There is.

The input port 11 is a port that receives a client signal via each device or communication line connected to the input port 11. The input port 11 outputs the received client signal to the client signal receiving unit 12. As the client signal, for example, SONET (Synchronous Optical Network), GbE (Gigabit Ethernet (registered trademark)), FC (Fiber Channel), OTN (Optical Transport Network), or the like is used. The client signal may be input as a plurality of signals from a plurality of paths. When the client signal is input from a plurality of routes, the input port 11 is provided for each route. Further, the client signal may be input via a wireless communication line.

The client signal receiving unit 12 converts the client signal transmitted from the input port 11 into a signal used inside the transmitting device 10. When the client signal receiving unit 12 converts the client signal into a signal format used inside the transmitting device 10, the converted client signal is output to the line signal transmitting unit 13.

The line signal transmission unit 13 generates a frame for transmission on the transmission line 30 based on the client signal input from the client signal reception unit 12. The line signal transmission unit 13 maps the input signal in the order of OPU (Optical channel Payload Unit), ODU (Optical channel Data Unit), and OTU (Optical Transport Unit), and generates a frame for transmission as an OTU frame. The line signal transmission unit 13 outputs a signal based on the OTU frame to the electro-optical conversion unit 14 as an OTU signal.

Further, the line signal transmission unit 13 adds an error correction code based on an error correction method set based on communication parameters when generating a frame for transmission based on the client signal. As the error correction method, for example, a low density parity check method or a forward error correction method is used.

The electric optical conversion unit 14 generates and outputs an optical signal to be transmitted on the transmission line 30. The electric light conversion unit 14 includes a light source and a modulator. The electric light conversion unit 14 modulates the light output from the light source based on the OTU signal input from the line signal transmission unit 13. The electric light conversion unit 14 outputs the modulated optical signal to the combine unit 15.

The light source of the electric light conversion unit 14 is composed of a semiconductor laser, and the wavelength of the output light is variable. The wavelength of the light output from the light source is set based on the communication parameter from among the wavelengths set based on the wavelength design of the communication system. Further, as the modulator, for example, an LN (Lithium Niobate) modulator is used. Further, when the transmission device 10 transmits a multiplexed signal in which a plurality of wavelengths are multiplexed, a light source and a modulator are provided for each wavelength. When the multiplex signal is transmitted, the optical signal of each wavelength is multiplexed and output by the combiner element. Further, the functions of the line signal transmission unit 13 and the electric light conversion unit 14 of the present embodiment correspond to the signal transmission means 1 of the first embodiment.

The combine unit 15 combines the electric light conversion unit 14 and the signal input from the parameter transmission unit 17. The combiner unit 15 outputs the combined multiplex signal to the transmission line 30. The combiner portion 15 is composed of, for example, an optical coupler.

The transmission control unit 16 has a function of controlling each part of the transmission device 10 so as to operate based on the setting of communication parameters. The communication parameter refers to information necessary for communication between the transmitting device 10 and the receiving device 20, such as the wavelength of an optical signal, a modulation method, a transmission rate, a frame format, and an error correction code. The transmission control unit 16 sets each part based on the initial setting communication parameters at the start of the operation of the transmission device 10. The default communication parameters are shared in advance between the transmitting device 10 and the receiving device 20. The default communication parameters are set as low priority communication parameters. The communication parameter having a low priority means a communication parameter corresponding to a setting that has a low transmission rate and is not suitable for normal high speed but can stably transmit an optical signal.

The transmission control unit 16 sets each part based on the information of the communication parameter sent from the parameter transmission unit 17 to the reception device 20. The transmission control unit 16 sets, for example, an error correction method in the line signal transmission unit 13. Further, the transmission control unit 16 sets the wavelength and modulation method of the optical signal output from the electric light conversion unit 14. The function of the transmission control unit 16 of the present embodiment corresponds to the transmission control means 3 of the first embodiment.

The parameter transmission unit 17 generates an optical signal based on the information of the communication parameter notified to the receiving device 20. The parameter transmission unit 17 outputs the generated optical signal to the combine unit 15. The parameter transmission unit 17 includes a communication parameter information generation unit, a light source, and a modulator. As the light source and the modulator, the same light source and the modulator as in the electric light conversion unit 14 can be used. The wavelength of the light source of the parameter transmission unit 17 is set to a wavelength that does not interfere with the optical signal output from the electric light conversion unit 14. The wavelength and modulation method of the optical signal output by the parameter transmission unit 17 are preset so that the optical signal can be transmitted and received to and from the receiving device 20. Further, the function of the parameter transmission unit 17 of the present embodiment corresponds to the parameter transmission means 2 of the first embodiment.

The configuration of the receiving device 20 will be described. FIG. 5 shows the configuration of the receiving device 20 of the present embodiment. The receiving device 20 includes an output port 21, a client signal transmitting unit 22, a line signal receiving unit 23, an opto-electrical conversion unit 24, a branching unit 25, a receiving control unit 26, and a parameter receiving unit 27. ..

The output port 21 is a port that outputs a client signal transmitted from the client signal transmission unit 22 to each device or communication line connected to the output port 21. When there are a plurality of routes to which the client signal is output, the output port 21 is provided so as to correspond to each route.

The client signal transmission unit 22 converts the client signal transmitted from the line signal reception unit 23 into a signal format for output from the reception device 20, and outputs the client signal to the output port 21.

The line signal receiving unit 23 performs demapping processing of the OTU signal received from the transmission line 30. The line signal receiving unit 23 outputs the demapping-processed signal to the client signal transmitting unit 22 as a client signal. When performing the demapping process of the OTU signal, the line signal receiving unit 23 performs error correction based on the error correction method set based on the communication parameters.

The optical-electric conversion unit 24 converts an optical signal input via the transmission line 30 into an electric signal. The opto-electric conversion unit 24 outputs an electric signal converted from the optical signal to the line signal receiving unit 23. The optical-electric conversion unit 24 converts an optical signal into an electric signal by a photodiode. The wavelength of the optical signal detected by the optical-electric conversion unit 24 is set based on the communication parameter from among the wavelengths set based on the wavelength design of the communication system. When the optical signal input from the transmission path 30 is a multiplex signal, the optical-electric conversion unit 24 separates the optical signal into optical signals of each wavelength by a demultiplexing element, and a photodiode provided for each optical signal of each wavelength. Converts an optical signal into an electrical signal. Further, the functions of the line signal receiving unit 23 and the opto-electrical conversion unit 24 of the present embodiment correspond to the signal receiving means 6 of the second embodiment.

The branching unit 25 branches the signal input from the transmission path 30 into optical signals of two paths, the optical electrical conversion unit 24 and the parameter receiving unit 27. The optical signal branched by the branching unit 25 and input to the optical / electrical conversion unit 24 and the parameter receiving unit 27 includes all wavelengths input from the transmission line 30 to the receiving device 20. The branch portion 25 is configured by using, for example, an optical coupler.

The reception control unit 26 sets each part based on the information of the communication parameter received from the transmission device 10. The reception control unit 26 sets the photoelectric conversion unit 24, the line signal reception unit 23, and the client signal transmission unit 22 based on the information of the communication parameters sent from the parameter reception unit 27. Further, the function of the reception control unit 26 of the present embodiment corresponds to the reception control means 8 of the second embodiment.

The parameter receiving unit 27 extracts communication parameter information from the signal transmitted from the transmitting device 10. The parameter receiving unit 27 outputs the extracted communication parameter information to the receiving control unit 26. The parameter receiving unit 27 includes a bandpass filter that passes the wavelength assigned to the notification of the communication parameter, a photoelectric conversion element using a photodiode, and a signal processing unit that extracts information on the communication parameter. The wavelength and modulation method of the optical signal received by the parameter receiving unit 27 are preset so that the optical signal can be transmitted and received to and from the transmitting device 10. Further, the function of the parameter receiving unit 27 of the present embodiment corresponds to the parameter detecting means 7 of the second embodiment.

The transmission line 30 is a communication line that transmits an optical signal. The transmission line 30 is composed of an optical fiber, a relay device, and the like.

The operation of the communication system of this embodiment will be described. First, the operation when the optimum communication parameter is notified from the transmitting device 10 to the receiving device 20 and the communication is established when the client signal is not transmitted / received, such as at the time of startup or after maintenance, will be described. do.

When the transmitting device 10 and the receiving device 20 are started up, the transmitting device 10 and the receiving device 20 start operating based on the default communication parameters. As the default communication parameter, a communication parameter having a lower priority is selected from the communication parameters supported by the transmitting device 10 and the receiving device 20.

When the transmission device 10 becomes operable by default, the parameter transmission unit 17 generates information on communication parameters to be notified to the reception device 20. As the communication parameter notified to the receiving device 20, the optimum communication parameter among the communication parameters supported by the transmitting device 10 and the receiving device 20, that is, the communication parameter having a high priority is selected. Communication parameters with high priority refer to error correction methods that have a high transmission rate and can perform error correction at a higher level.

FIG. 6 shows an example of communication parameters set in the communication system of the present embodiment. In FIG. 6, as communication parameter items, a modulation method, a line-side signal bit rate indicating a bit rate at the time of transmission on the transmission line 30, an optical signal wavelength, and an error correction method are set. In FIG. 6, SD-FEC (Soft Decision-Forward Error Correction) and HD-FEC (Hard Decision-Forward Error Correction) are set as error correction methods. In FIG. 6, the priority of each item at the top of the table is set to be high. Further, among the communication parameters, the wavelength of the optical signal may be selected based on the wavelength design of the communication system without setting the priority.

When the parameter transmission unit 17 generates communication parameter information, it converts it into an optical signal. The parameter transmission unit 17 outputs an optical signal converted from the information of the communication parameter to the transmission line 30 via the combine unit 15.

The optical signal output from the transmitting device 10 is transmitted through the transmission line 30 and input to the receiving device 20. The optical signal input to the receiving device 20 is branched by the branching unit 25 and input to the optical electrical conversion unit 24 and the parameter receiving unit 27. At this time, the optical signal input to the parameter receiving unit 27 is not processed because the wavelength is different from the optical signal processed by the optical-electric conversion unit 24.

When an optical signal is input to the parameter receiving unit 27, the parameter receiving unit 27 converts the input optical signal into an electric signal. When the parameter receiving unit 27 converts an optical signal into an electric signal, the parameter receiving unit 27 extracts communication parameter information from the converted signal. When the communication parameter information is extracted, the parameter receiving unit 27 sends the communication parameter information to the receiving control unit 26.

When the reception control unit 26 receives the information of the communication parameter, the reception control unit 26 sets the optical / electrical conversion unit 24, the line signal reception unit 23, and the client signal transmission unit 22 based on the received information. When the opto-electric conversion unit 24, the line signal receiving unit 23, and the client signal transmitting unit 22 are set, the receiving device 20 can communicate based on the communication parameters shared by the notification from the transmitting device 10 to the receiving device 20. It becomes a state.

Further, the transmission control unit 16 of the transmission device 10 sets each part based on the information of the communication parameters sent from the parameter transmission unit 17 to the reception device 20. The transition from the initial setting state of the transmission device 10 to the setting based on the communication parameter having a high priority is performed, for example, after a predetermined time from the transmission of the communication parameter. The predetermined time is set to be longer than the time required for the receiving device 20 to change the setting after transmitting the communication parameter. Further, the transmission device 10 may shift from the initial setting state to the setting based on the communication parameter having a high priority when a new client signal is input.

When the transmitting device 10 and the receiving device 20 are in a state in which communication is possible based on the communication parameters shared by the notification from the transmitting device 10 to the receiving device 20, the transmitting device 10 is a client based on the newly set communication parameters. The signal is transmitted to the receiving device 20.

Next, when the optical signal based on the client signal is being transmitted, the communication parameter is notified from the transmitting device 10 to the receiving device 20, and the operation when the communication parameter is adjusted will be described.

When a client signal is input to the input port 11 of the transmission device 10, the input port 11 outputs the client signal to the client signal receiving unit 12. When the client signal receiving unit 12 receives the client signal, the client signal receiving unit 12 converts the client signal into a signal of the format used in the transmitting device 10. When converted into a signal of the format used by the transmission device 10, the client signal receiving unit 12 sends the converted client signal to the line signal transmitting unit 13. Upon receiving the client signal from the client signal receiving unit 12, the line signal transmitting unit 13 performs mapping processing based on the received signal and generates a frame for transmission as an OTU frame.

When the line signal transmission unit 13 generates an OTU frame, the line signal transmission unit 13 outputs an OTU signal based on the generated OTU frame to the electro-optical conversion unit 14. Upon receiving the OTU signal, the electric light conversion unit 14 modulates the light output from the light source based on the received OTU signal to generate an optical signal for transmission. When the light is modulated based on the OTU signal to generate an optical signal, the electro-optical conversion unit 14 sends the modulated optical signal to the combine unit 15.

Further, the parameter transmission unit 17 generates data for notifying the receiving device 20 of the communication parameter information. As the communication parameter, the parameter transmission unit 17 selects the setting having the highest priority among the communication parameters such as the modulation method, wavelength, and bit rate that the transmission device 10 and the reception device 20 commonly support. When the communication parameter having the highest priority has already been set and a problem has occurred, the parameter transmission unit 17 selects the communication parameter having one lower priority.

The generation of communication parameter information for notifying the receiving device 20 by the parameter transmitting unit 17 starts when the transmitting device 10 detects that communication has not been established or when the operator inputs resetting. Will be done.

When the parameter transmission unit 17 generates information on communication parameters to be notified to the receiving device 20, the generated data is converted into an optical signal. The parameter transmission unit 17 outputs an optical signal converted from the communication parameter information to the combine unit 15.

When an optical signal is input to the combined wave unit 15 from the electric optical conversion unit 14 and the parameter transmission unit 17, the combined wave unit 15 outputs the optical signal to the multiplexed transmission line 30. The multiplexed optical signal is transmitted through the transmission line 30 and input to the receiving device 20.

The optical signal input to the receiving device 20 is branched by the branching unit 25 and sent to the photoelectric conversion unit 24 and the parameter receiving unit 27, respectively.

When an optical signal is input to the opto-electric conversion unit 24, the opto-electric conversion unit 24 converts the input optical signal into an electric signal and outputs it to the line signal receiving unit 23. The line signal receiving unit 23 demaps the OTU frame, which receives the electric signal converted from the optical signal, and converts it into a client signal. The line signal receiving unit 23 outputs the converted client signal to the client signal transmitting unit 22.

When the client signal transmission unit 22 receives the client signal from the line signal reception unit 23, the client signal transmission unit 22 converts it into a signal format for output from the reception device 20. After converting the signal format, the client signal transmission unit 22 sends the converted client signal to the output port 21. When the output port 21 receives a client signal from the client signal transmission unit 22, the output port 21 transmits the received client signal to a device or a communication line connected to the output port 21.

Further, when an optical signal is input from the branch unit 25 to the parameter receiving unit 27, the parameter receiving unit 27 converts the input optical signal into an electric signal. When the parameter receiving unit 27 converts an optical signal into an electric signal, the parameter receiving unit 27 extracts communication parameter information from the converted signal. When the communication parameter information is extracted, the parameter receiving unit 27 sends the communication parameter information to the receiving control unit 26.

When the reception control unit 26 receives the information of the communication parameter, the reception control unit 26 sets the optical / electrical conversion unit 24, the line signal reception unit 23, and the client signal transmission unit 22 based on the received information. When the opto-electric conversion unit 24, the line signal receiving unit 23, and the client signal transmitting unit 22 are set, the receiving device 20 can communicate based on the communication parameters shared by the notification from the transmitting device 10 to the receiving device 20. It becomes a state.

Further, the transmission control unit 16 of the transmission device 10 sets each part based on the information of the communication parameters sent from the parameter transmission unit 17 to the reception device 20. The change of the communication parameter setting of the transmission device 10 is performed, for example, after a predetermined time from the transmission of the communication parameter. The predetermined time is set to be longer than the time required for the receiving device 20 to change the setting after transmitting the communication parameter. Further, the transmission device 10 may change the setting of the communication parameter when a new client signal is input.

When the transmitting device 10 and the receiving device 20 are in a state where communication is possible based on the communication parameters shared by the notification from the transmitting device 10 to the receiving device 20, the transmitting device 10 sends a client signal based on the newly set communication parameters. Is transmitted to the receiving device 20.

When the communication system of the present embodiment is operating based on the initial setting, that is, the communication parameter having a low priority, the transmitting device 10 notifies the receiving device 20 of the information of the optimum communication parameter having a high priority. ing. By notifying the receiving device 20 of the information of the optimum communication parameter from the transmitting device 10, the information of the optimum communication parameter can be shared between the transmitting device 10 and the receiving device 20. By sharing the information of the optimum communication parameter between the transmitting device 10 and the receiving device 20, the transmitting device 10 and the receiving device 20 automatically shift to the setting state based on the optimum communication parameter, and the optimum communication parameter. It is possible to perform communication based on. Further, in the communication system of the present embodiment, the communication parameters can be reset even when the optical signal based on the client signal is transmitted / received, so that the communication cannot be established or the communication quality is low. It is also possible to deal with such cases.

Further, in the communication system of the present embodiment, information on communication parameters is transmitted from the transmitting device 10 to the receiving device 20 via a transmission line 30 for transmitting an optical signal based on a client signal. Therefore, the communication system of the present embodiment does not require a complicated configuration for the operation of sharing communication parameter information between the transmitting device 10 and the receiving device 20 and changing the communication parameters used for transmitting and receiving optical signals. It can be done automatically. From the above, the communication system of the present embodiment can easily set communication parameters and establish communication based on the optimum communication parameters.

(Fourth Embodiment)
A fourth embodiment of the present invention will be described in detail with reference to the drawings. FIG. 7 shows an outline of the configuration of the communication system of the present embodiment. In the communication system of the third embodiment, when the communication parameter is notified, the transmitting device generates an optical signal for notification and transmits it to the receiving device. However, the communication system of the present embodiment has the communication parameter. It is characterized in that information is superimposed on a main signal and transmitted.

The communication system of the present embodiment includes a transmitting device 40 and a receiving device 50. Further, the transmitting device 40 and the receiving device 50 are connected to each other via a transmission line 30. The configuration of the transmission line 30 of this embodiment is the same as that of the third embodiment. Similar to the third embodiment, the communication system of the present embodiment is an optical communication network that transmits a client signal input to the transmitting device 40 to the receiving device 50 as an optical signal via a transmission line 30.

The configuration of the transmission device 40 will be described. FIG. 8 shows the configuration of the transmission device 40 of the present embodiment. The transmission device 40 includes an input port 41, a client signal reception unit 42, a line signal transmission unit 43, an electro-optical conversion unit 44, a transmission control unit 45, and a parameter transmission unit 46.

The configurations and functions of the input port 41, the client signal receiving unit 42, the line signal transmitting unit 43, and the transmission control unit 45 of the present embodiment are the same as those of the third embodiment having the same name.

The electric optical conversion unit 44 has a function of modulating an optical signal based on a signal input from the parameter transmission unit 46 in addition to the signal input from the line signal transmission unit 43. The electric light conversion unit 44 performs modulation based on the OTU signal input from the line signal transmission unit 43 to generate a main signal. Further, the electric light conversion unit 44 further modulates the main signal based on the signal input from the parameter transmission unit 46. The electric light conversion unit 44 performs modulation at a lower frequency than the main signal based on the signal input from the parameter transmission unit 46. The low frequency refers to a frequency band that does not affect the reception device 50 when the main signal modulated based on the signal input from the line signal transmission unit 43 is detected.

FIG. 9 shows an example of the configuration of the electro-optical conversion unit 44 of the present embodiment. The electric light conversion unit 44 of FIG. 9 includes an optical output unit 201, a first modulation unit 202, and a second modulation unit 203.

The optical output unit 201 includes a semiconductor laser and outputs an optical signal having a predetermined wavelength. The predetermined wavelength is set based on the wavelength design and communication parameters of the communication system. The first modulation unit 202 modulates the light input from the optical output unit 201 to generate a main signal based on the signal input from the line signal transmission unit 43, and outputs the main signal to the second modulation unit 203. do. Further, the second modulation unit 203 further modulates the main signal input from the first modulation unit 202 based on the signal input from the parameter transmission unit 46, and outputs the modulation to the transmission line 30.

The parameter transmission unit 46 generates information on communication parameters to be notified to the receiving device 50. The parameter transmission unit 46 outputs the generated communication parameter information to the electro-optical conversion unit 44.

The configuration of the receiving device 50 will be described. FIG. 10 shows the configuration of the receiving device 50 of the present embodiment. The receiving device 50 includes an output port 51, a client signal transmitting unit 52, a line signal receiving unit 53, an opto-electrical conversion unit 54, a receiving control unit 55, and a parameter receiving unit 56.

The configurations and functions of the output port 51, the client signal transmitting unit 52, the line signal receiving unit 53, and the receiving control unit 55 of the present embodiment are the same as those of the third embodiment having the same name.

The optical-electric conversion unit 54 converts an optical signal input via the transmission line 30 into an electric signal. The optical-electric conversion unit 54 outputs the main signal among the electrical signals converted from the optical signal to the line signal receiving unit 53. The optical-electric conversion unit 54 sends a low-frequency component of the electric signal converted from the optical signal to the parameter receiving unit 56. The opto-electric conversion unit 54, for example, divides the electric signal converted from the optical signal into two, and each of the line signal receiving unit 53 and the line signal receiving unit 53 via a bandpass filter that blocks components other than the region to be detected. Only the signals in the required area are passed by the parameter receiving unit 56.

The parameter receiving unit 56 extracts communication parameter information from the signal input from the opto-electrical conversion unit 54. The parameter receiving unit 56 outputs the extracted communication parameter information to the receiving control unit 55.

In the communication system of the present embodiment, the operation when the transmitting device 40 notifies the receiving device 50 of the communication parameters and the communication is established will be described.

When the transmitting device 40 and the receiving device 50 are started up, the transmitting device 40 and the receiving device 50 each start operating based on the default communication parameters. The default communication parameters are set as low priority communication parameters. When the transmitting device 40 becomes operable by default, the parameter transmitting unit 46 generates information on the optimum communication parameter for notifying the receiving device 50. When the communication parameter information is generated, the parameter transmission unit 46 sends the generated data to the electro-optical conversion unit 44. The selection of the optimum communication parameter is performed in the same manner as in the third embodiment.

The electric light conversion unit 44 further modulates the modulated optical signal based on the OTU signal input from the line signal transmission unit 43 based on the signal input from the parameter transmission unit 46. When the client signal is not input to the transmission device 40, the electro-optical conversion unit 44 applies an optical signal based only on the signal input from the parameter transmission unit 46. The optical signal modulated by the electric light conversion unit 44 is transmitted through the transmission line 30 and input to the receiving device 50.

The optical signal input to the receiving device 50 is converted into an electric signal by the optical-electric conversion unit 54, and is input to the line signal receiving unit 53 and the parameter receiving unit 56. The signal input to the line signal receiving unit 53 is processed in the same manner as in the third embodiment, and is output from the receiving device 50 as a client signal.

When a signal is input to the parameter receiving unit 56, the parameter receiving unit 56 extracts communication parameter information from the signal input from the opto-electrical conversion unit 54. The parameter receiving unit 56 outputs the extracted communication parameter information to the receiving control unit 55.

When the reception control unit 55 receives the information of the communication parameter, the reception control unit 55 sets the optical / electrical conversion unit 54, the line signal reception unit 53, and the client signal transmission unit 52 based on the received information. When the opto-electric conversion unit 54, the line signal receiving unit 53, and the client signal transmitting unit 52 are set, the receiving device 50 can communicate based on the communication parameters shared by the notification from the transmitting device 40 to the receiving device 50. It becomes a state.

The transition from the initial setting state of the transmission device 40 to the setting based on the communication parameter having a high priority can be performed in the same manner as in the third embodiment.

When the transmitting device 40 and the receiving device 50 are in a state where communication is possible based on the communication parameters shared by the notification from the transmitting device 40 to the receiving device 50, the transmitting device 40 receives a client signal based on the newly set communication parameters. Is transmitted to the receiving device 50. Further, not only when communication is established, but also communication parameters can be reset by the same operation as described above.

The communication system of the present embodiment has the same effect as that of the third embodiment. Further, in the communication system of the present embodiment, the information of the communication parameter is superimposed on the main signal transmitted from the transmitting device 40 to the receiving device 50, and the transmitting device 40 notifies the receiving device 50. Therefore, in the communication system of the present embodiment, the number of optical elements required for transmitting the information of the communication parameter can be reduced, so that the configurations of the transmitting device 40 and the receiving device 50 can be further simplified.

(Fifth Embodiment)
A fifth embodiment of the present invention will be described in detail with reference to the drawings. FIG. 11 shows the configuration of the communication system of the present embodiment. In the communication system of the third embodiment, when the communication parameter is notified, the transmitting device generates an optical signal for notification and transmits it to the receiving device. However, in the communication system of the present embodiment, the main signal is used. It is characterized by inserting communication parameter information into a frame and notifying it.

The communication system of the present embodiment includes a transmitting device 60 and a receiving device 70. Further, the transmitting device 60 and the receiving device 70 are connected to each other via a transmission line 30. The configuration of the transmission line 30 of this embodiment is the same as that of the third embodiment. Similar to the third embodiment, the communication system of the present embodiment is an optical communication network that transmits a client signal input to the transmitting device 60 to the receiving device 70 as an optical signal via a transmission line 30.

The configuration of the transmission device 60 will be described. FIG. 12 shows the configuration of the transmission device 60 of the present embodiment. The transmission device 60 includes an input port 61, a client signal reception unit 62, a line signal transmission unit 63, an electro-optical conversion unit 64, a transmission control unit 65, and a parameter transmission unit 66.

The configurations and functions of the input port 61, the client signal receiving unit 62, the electric light conversion unit 64, and the transmission control unit 65 of the present embodiment are the same as those of the third embodiment having the same name.

The line signal transmission unit 63 adds the same function as the line signal transmission unit 13 of the third embodiment, and adds communication parameter information to a predetermined area of the ODU frame. A predetermined area is set in an area of the ODU frame that is not used for other purposes. FIG. 13 shows an example of the frame configuration of the present embodiment. The line signal transmission unit 63 adds communication parameter information to a region of the ODU frame that is not used for other purposes. The line signal transmission unit 63, for example, adds communication parameter information to the “Reserved” region of the ODU frame.

The parameter transmission unit 66 generates information on communication parameters to be notified to the receiving device 70. The parameter transmission unit 66 outputs the generated communication parameter information to the line signal transmission unit 63. The parameter transmission unit 66 selects communication parameters in the same manner as the parameter transmission unit 17 of the third embodiment.

The configuration of the receiving device 70 will be described. FIG. 14 shows the configuration of the receiving device 70 of the present embodiment. The receiving device 70 includes an output port 71, a client signal transmitting unit 72, a line signal receiving unit 73, an opto-electrical conversion unit 74, a parameter receiving unit 76, and a receiving control unit 75.

The configurations and functions of the output port 71, the client signal transmission unit 72, the opto-electric conversion unit 74, and the reception control unit 75 of the present embodiment are the same as those of the third embodiment having the same name.

The line signal receiving unit 73 confirms whether or not the communication parameter information is written in the predetermined area of the ODU frame when the demapping is performed. In the present embodiment, the line signal receiving unit 73 refers to the “Reserved” area of the ODU frame and confirms whether or not the communication parameter information is written. When the communication parameter information is written in the predetermined area of the ram, the line signal receiving unit 73 outputs the communication parameter information to the parameter receiving unit 76. When the parameter receiving unit 76 receives the communication parameter information from the line signal receiving unit 73, the parameter receiving unit 76 outputs the received communication parameter information to the receiving control unit 75.

In the communication system of the present embodiment, the operation when the transmitting device 60 notifies the receiving device 70 of the communication parameters and the communication is established will be described.

When the transmitting device 60 and the receiving device 70 are started up, the transmitting device 60 and the receiving device 70 each start operating based on the default communication parameters. The default communication parameters are set as low priority communication parameters. When the transmitting device 60 becomes operable by default, the parameter transmitting unit 66 generates information on the optimum communication parameter for notifying the receiving device 70.

When the communication parameter information is generated, the parameter transmission unit 66 generates the communication parameter information to be notified to the receiving device 70 by the parameter transmission unit 66. When the data for notifying the receiving device 70 is generated, the parameter transmitting unit 66 sends the communication parameter information to the line signal transmitting unit 63. Upon receiving the communication parameter information, the line signal transmission unit 63 writes the communication parameter information in a predetermined area of the ODU frame. The ODU frame in which the communication parameter information is written is generated as an OTU frame by the mapping that is advanced in order. The OTU frame generated by the line signal transmission unit 63 is converted into an optical signal by the electro-optical conversion unit 64 as an OTU signal. The OTU signal in which the communication parameter information is written is transmitted through the transmission line 30 as an optical signal and input to the receiving device 70.

The optical signal input to the receiving device 70 is converted into an electric signal by the optical-electric conversion unit 74 and sent to the line signal receiving unit 73. When a signal is input to the line signal receiving unit 73, demapping is performed. The demapping processed OTU frame is output from the receiving device 70 as a client signal via the client signal transmitting unit 72 and the output port 71.

Further, when the demapping process is performed in the line signal receiving unit 73, the parameter receiving unit 76 refers to the ODU frame and confirms whether or not the communication parameter information is written in the predetermined area. When the parameter receiving unit 76 detects the communication parameter information, the parameter receiving unit 76 outputs the detected communication parameter information to the receiving control unit 75.

When the reception control unit 75 receives the information of the communication parameter, the reception control unit 75 sets the optical / electrical conversion unit 74, the line signal reception unit 73, and the client signal transmission unit 72 based on the received information. Further, the transition from the initial setting state of the transmission device 60 to the setting based on the communication parameter having a high priority can be performed in the same manner as in the third embodiment.

When the communication parameters of the transmitting device 60 and the receiving device 70 are set, the transmitting device 60 and the receiving device 70 are in a state of being able to communicate based on the communication parameters shared by the notification from the transmitting device 60 to the receiving device 70. ..

The communication system of the present embodiment has the same effect as that of the third embodiment. Further, in the communication system of the present embodiment, the information of the communication parameter is added to the transmission frame transmitted from the transmission device 60 to the reception device 70 and notified. Therefore, in the communication system of the present embodiment, the number of optical elements required for transmitting the information of the communication parameter can be reduced, so that the configurations of the transmitting device 60 and the receiving device 70 can be further simplified.

(Sixth Embodiment)
A sixth embodiment of the present invention will be described in detail with reference to the drawings. FIG. 15 shows an outline of the configuration of the communication system of the present embodiment. In the communication system of the fourth embodiment, an optical signal in which a signal based on communication parameter information is superimposed is transmitted from a transmitting device to a receiving device, but in the communication system of the present embodiment, the optical signal is bidirectionally transmitted. It is characterized by performing transmission.

The communication system of the present embodiment includes a first communication device 81 and a second communication device 82. The first communication device 81 and the second communication device 82 are connected to each other via the transmission line 30 and the transmission line 31. The communication system of the present embodiment transmits the client signal input to the first communication device 81 to the second communication device 82 as an optical signal via the transmission line 30. Further, the communication system of the present embodiment transmits the client signal input to the second communication device 82 to the first communication device 81 as an optical signal via the transmission path 31.

The configuration of the communication device 100 used as the first communication device 81 and the second communication device 82 will be described. FIG. 16 shows an outline of the configuration of the communication device 100.

The communication device 100 includes an input port 101, a client signal receiving unit 102, a line signal transmitting unit 103, an electro-optical conversion unit 104, a setting control unit 105, and a parameter transmitting / receiving unit 106. Further, the communication device 100 further includes an output port 111, a client signal transmission unit 112, a line signal reception unit 113, and an optical / electrical conversion unit 114.

The configuration and function of the input port 101, the client signal receiving unit 102, and the line signal transmitting unit 103 of the present embodiment are the same as the parts of the same name of the transmitting device 10 of the third embodiment. Further, the configurations and functions of the output port 111, the client signal transmitting unit 112, and the line signal receiving unit 113 of the present embodiment are the same as the parts of the same name of the receiving device 20 of the third embodiment.

The electric optical conversion unit 104 has a function of modulating an optical signal based on a signal input from the parameter transmission / reception unit 106 in addition to the signal input from the line signal transmission unit 103. The electric light conversion unit 104 further modulates the main signal generated by modulation based on the signal input from the line signal transmission unit 103 based on the signal input from the parameter transmission / reception unit 106. The electric light conversion unit 104 can have the same configuration as the electric light conversion unit 44 of the fourth embodiment, for example.

The parameter transmission / reception unit 106 outputs a signal based on the communication parameter information to the electro-optical conversion unit 104. Further, the parameter transmission / reception unit 106 extracts information indicating whether or not the communication parameter can be changed from the signal input from the photoelectric conversion unit 114. When the information indicating whether or not the extracted communication parameter can be changed indicates that the change is possible, the parameter transmission / reception unit 106 outputs the set value of the changed communication parameter and the information requesting the change to the setting control unit 105. ..

Further, when the communication parameter information is sent from the communication device of the communication partner, the parameter transmission / reception unit 106 determines whether the setting based on the communication parameter information is possible in the own device. The parameter transmission / reception unit 106 outputs information on whether or not the communication parameter can be changed to the electro-optical conversion unit 104 and transmits the information to the communication device of the communication partner.

The optical-electric conversion unit 114 converts an optical signal input via the transmission line 31 into an electric signal. The opto-electric conversion unit 114 outputs the main signal among the electrical signals converted from the optical signal to the line signal receiving unit 113. The optical-electric conversion unit 114 sends a low-frequency component of the electrical signal converted from the optical signal to the parameter transmission / reception unit 106.

When the setting control unit 105 receives the setting value of the communication parameter and the information requesting the change from the parameter transmission / reception unit 106, the setting control unit 105 controls each part and changes the setting of the communication parameter.

The transmission line 31 has the same configuration as the transmission line 30 of the third embodiment.

In the communication system of the present embodiment, the operation when the information of the new communication parameter is transmitted from the first communication device 81 to the second communication device 82 and the setting of the communication parameter is changed will be described.

When the change of the communication parameter setting is started, the parameter transmission / reception unit 106 of the first communication device 81 generates the information of the changed communication parameter. When the parameter transmission / reception unit 106 generates the changed communication parameter information, the parameter transmission / reception unit 106 outputs a signal based on the communication parameter information to the electro-optical conversion unit 104. Upon receiving the signal based on the communication parameter information, the electro-optical conversion unit 104 modulates the main signal generated based on the OTU signal input from the line signal transmission unit 103 based on the communication parameter information, and performs a transmission path. Output to 30.

The optical signal transmitted through the transmission path 30 is input to the optical-electric conversion unit 114 of the second communication device 82. The optical-electric conversion unit 114 converts the input optical signal into an electric signal, and outputs a signal in the low frequency region to the parameter transmission / reception unit 106.

When the signal is input, the parameter transmission / reception unit 106 extracts the communication parameter information from the data of the received signal. When the information of the communication parameter is extracted, the parameter transmission / reception unit 106 determines whether the communication parameter can be set by the own device.

FIG. 17 shows an example of data showing the priority and the possibility of setting for each communication parameter. In addition to the same configuration as the data table of FIG. 6, FIG. 17 includes information on whether or not each communication parameter can be supported. In the example of FIG. 17, when the correspondence is possible, it is shown as “◯”, and when the correspondence is added, it is shown as “x”.

When it is determined whether or not the communication parameter can be set by the own device, the parameter transmission / reception unit 106 transmits information indicating whether or not the communication parameter can be set to the transmission line 31 via the electro-optical conversion unit 104.

The optical signal transmitted to the transmission path 31 is input to the optical-electric conversion unit 114 of the first communication device 81. When the optical signal is input, the optical-electric conversion unit 114 converts the optical signal into an electric signal and outputs it to the parameter transmission / reception unit 106. Upon receiving the information indicating whether or not the communication parameter can be set, the parameter transmission / reception unit 106 selects the communication parameter having the highest priority among the settable communication parameters. When the communication parameter is selected, the parameter transmission / reception unit 106 sends the information of the selected communication parameter and the information requesting the change of the communication parameter to the setting control unit 105. When the setting control unit 105 receives the setting value of the communication parameter and the information requesting the change from the parameter transmission / reception unit 106, the setting control unit 105 controls each part and changes the setting of the communication parameter.

Further, the parameter transmission / reception unit 106 of the second communication device 82 sends the communication parameter information and the information requesting the change of the setting to the setting control unit 105 in order to change the setting value of the own device. The parameter transmission / reception unit 106 of the second communication device 82 selects the communication parameter having the highest priority among the communication parameters returned as configurable to the first communication device 81. When the communication parameter is selected, the setting control unit 105 controls each part to change the communication parameter setting when it receives the communication parameter setting value and the information requesting the change from the parameter transmission / reception unit 106.

When the set values of the communication parameters of the first communication device 81 and the second communication device 82 are changed, optical signals are transmitted and received based on the changed set values. Further, in the communication system of the present embodiment, the transmission / reception of the client signal can be performed in the same manner as in the fourth embodiment.

The communication system of the present embodiment has the same effect as the communication system of the third and fourth embodiments. Further, the communication system of the present embodiment transmits / receives information on whether or not communication parameters can be set by bidirectional communication. Therefore, in the communication system of the present embodiment, the optimum communication parameters can be set more reliably.

(7th Embodiment)
A seventh embodiment of the present invention will be described in detail with reference to the drawings. FIG. 18 shows an outline of the configuration of the communication system of the present embodiment. In the communication system of the fifth embodiment, an optical signal in which information of communication parameters is added to a predetermined area of a frame is transmitted from a transmitting device to a receiving device, but the communication system of the present embodiment is bidirectional. It is characterized by transmitting optical signals.

The communication system of the present embodiment includes a first communication device 91 and a second communication device 92. The first communication device 91 and the second communication device 92 are connected to each other via the transmission line 30 and the transmission line 31. The communication system of the present embodiment transmits the client signal input to the first communication device 91 to the second communication device 92 as an optical signal via the transmission line 30. Further, the communication system of the present embodiment transmits the client signal input to the second communication device 92 to the first communication device 91 as an optical signal via the transmission path 31.

The configuration of the communication device 120 used as the first communication device 91 and the second communication device 92 will be described. FIG. 19 shows an outline of the configuration of the communication device 120 of the present embodiment.

The communication device 120 includes an input port 121, a client signal receiving unit 122, a line signal transmitting unit 123, an electro-optical conversion unit 124, a setting control unit 125, and a parameter transmitting / receiving unit 126. Further, the communication device 120 further includes an output port 131, a client signal transmission unit 132, a line signal reception unit 133, and an optical / electrical conversion unit 134.

The configuration and function of the input port 121 of the present embodiment, the client signal receiving unit 122, and the electric light conversion unit 124 are the same as the parts of the same name of the transmitting device 10 of the third embodiment. Further, the configuration and function of the output port 131, the client signal transmission unit 132, and the optical / electrical conversion unit 134 of the present embodiment are the same as the parts of the same name of the receiving device 20 of the third embodiment.

The line signal transmission unit 123 adds the same function as the line signal transmission unit 13 of the third embodiment, and adds communication parameter information to the transmission frame. Further, when the line signal transmission unit 123 receives the information on whether or not the communication parameter can be set from the parameter transmission / reception unit 126, the line signal transmission unit 123 adds the information on whether or not the communication parameter can be set to a predetermined area of the ODU frame.

The parameter transmission / reception unit 126 has the same function as the parameter transmission unit 17 of the third embodiment. The parameter transmission / reception unit 126 outputs information on communication parameters to be notified to the communication device of the communication partner to the line signal transmission unit 123.

Upon receiving the communication parameter information, the parameter transmission / reception unit 126 determines whether or not the setting is possible in the own device. The parameter transmission / reception unit 126 outputs information on whether or not the communication parameter can be set by the own device to the line signal transmission unit 123.

When the communication parameter information is added to the demapped ODU frame, the line signal reception unit 133 outputs the communication parameter information to the parameter transmission / reception unit 126. Further, when the information on whether or not the communication parameter can be changed is added to the data of the demapped ODU frame, the line signal receiving unit 133 outputs the information on whether or not the communication parameter can be changed to the parameter transmission / reception unit 126. ..

In the communication system of the present embodiment, a case where new communication parameter setting values are transmitted from the first communication device 91 to the second communication device 92 and the communication parameters are changed will be described as an example.

When the change of the communication parameter setting is started, the parameter transmission / reception unit 126 of the first communication device 91 generates the information of the changed communication parameter. The operation of changing the communication parameter settings is performed when communication is established or when the expected communication quality is not obtained. When the information of the changed communication parameter is generated, the parameter transmission / reception unit 126 outputs the information to the line signal transmission unit 123. When the line signal transmission unit 123 receives the information of the communication parameter, it adds it to a predetermined area of the ODU frame. The addition of the communication parameter information to the ODU frame can be performed in the same manner as in the fifth embodiment.

The OTU frame to which the information of the communication parameter is added is converted into an optical signal by the electro-optical conversion unit 124. The electric optical conversion unit 124 outputs an optical signal converted from an OTU frame in which communication parameter information is written to a transmission line 30.

The optical signal transmitted through the transmission path 30 is input to the optical-electric conversion unit 134 of the second communication device 92. The optical-electric conversion unit 134 converts the input optical signal into an electric signal and sends it to the line signal receiving unit 133. When a signal is input to the line signal receiving unit 133, demapping processing is performed. The line signal receiving unit 133 confirms whether or not the communication parameter information is written in the predetermined area of the demapped ODU frame. When the line signal receiving unit 133 detects the communication parameter information, the line signal receiving unit 133 outputs the detected communication parameter information to the line signal receiving unit 133.

When the information of the communication parameter is input, the parameter transmission / reception unit 126 determines whether the communication parameter can be set by the own device.

When it is determined whether or not the setting is possible by the own device, the parameter transmission / reception unit 126 outputs information indicating whether or not the setting is possible for each communication parameter to the line signal transmission unit 123. Upon receiving the information indicating whether or not the communication parameter can be set, the line signal transmission unit 123 adds the information on whether or not the communication parameter can be set to a predetermined area of the ODU frame. The information indicating whether or not the communication parameter can be set is added to the same area as the area to which the communication parameter information is added.

The OTU frame to which the information on whether or not the communication parameter can be set is added is converted into an optical signal by the electro-optical conversion unit 124. The optical signal based on the OTU frame in which the information on whether or not the communication parameter can be set is written is transmitted through the transmission line 31 and input to the first communication device 91.

The optical-electric conversion unit 134 of the first communication device 91 converts the input optical signal into an electric signal and sends it to the line signal receiving unit 133. When a signal is input to the line signal receiving unit 133, the line signal receiving unit 133 performs demapping processing. When the line signal receiving unit 133 performs the demapping process, it confirms whether or not the information indicating whether or not the communication parameter can be set is written in the predetermined area of the ODU frame. When the information indicating whether or not the communication parameter can be set is detected, the line signal receiving unit 133 outputs the detected information to the parameter transmitting / receiving unit 126. Upon receiving the information indicating whether or not the communication parameter can be set, the parameter transmission / reception unit 126 selects the communication parameter having the highest priority among the settable communication parameters. When the communication parameter is selected, the parameter transmission / reception unit 126 sends the information of the selected communication parameter and the information requesting the change of the communication parameter to the setting control unit 125. When the setting control unit 125 receives the setting value of the communication parameter and the information requesting the change from the parameter transmission / reception unit 126, the setting control unit 125 controls each part and changes the setting of the communication parameter.

Further, the parameter transmission / reception unit 126 of the second communication device 92 sends the communication parameter information and the information requesting the change of the setting to the setting control unit 125 in order to change the setting value of the own device. The parameter transmission / reception unit 126 of the second communication device 92 selects the communication parameter having the highest priority among the communication parameters returned as configurable to the first communication device 81. When the communication parameter is selected, the setting control unit 125 controls each part to change the communication parameter setting when it receives the communication parameter setting value and the information requesting the change from the parameter transmission / reception unit 126.

When the set values of the communication parameters of the first communication device 91 and the second communication device 92 are changed, optical signals are transmitted and received based on the changed set values. Further, in the communication system of the present embodiment, the transmission / reception of the client signal can be performed in the same manner as in the fifth embodiment.

The communication system of the present embodiment has the same effect as the communication system of the third and fifth embodiments. Further, the communication system of the present embodiment transmits / receives information on whether or not communication parameters can be set by bidirectional communication. Therefore, in the communication system of the present embodiment, the optimum communication parameters can be set more reliably.

When the information of the communication parameter is transmitted from the transmitting device to the receiving device in the third to fifth embodiments, the information indicating the timing of changing the setting may also be transmitted. By notifying the receiving device of the information indicating the timing of changing the setting from the transmitting device, it is possible to accurately match the timing of changing the setting of the communication parameter.

The methods for sharing communication parameter information in the third to fifth embodiments may be used in combination with each other. For example, when establishing communication at the time of startup, communication parameters are shared by the method of the third or fourth embodiment, and when adjusting communication parameters, communication parameters are shared by the method of the fifth embodiment. Then, the communication parameters may be changed. By changing the method of sharing and setting communication parameter information between when communication is established at startup and during normal operation, communication parameter information is shared and set by a method suitable for the communication status. It can be performed.

In a configuration for bidirectional communication such as the communication system of the fifth and sixth embodiments, the optical signal based on the information of the communication parameter may be multiplexed and transmitted as in the third embodiment. Further, in the communication systems of the fifth and sixth embodiments, after one communication device receives information on whether or not the communication parameter can be set, the other communication parameter is actually set and the timing for changing the setting is changed. The communication device may be notified. With such a configuration, it is possible to accurately change the setting of the communication parameter without causing a timing difference between the communication devices.

Some or all of the above embodiments may also be described, but not limited to:

(Appendix 1)
A signal transmission means that transmits an optical signal via a transmission line,
When the signal transmitting means transmits the optical signal based on the first communication parameter, the parameter transmitting means for transmitting the information of the second communication parameter via the transmission path and the parameter transmitting means.
A transmission control means that controls the signal transmission means to transmit the optical signal based on the second communication parameter after transmitting the information of the second communication parameter.
A transmitter characterized by comprising.

(Appendix 2)
The parameter transmitting means selects the communication parameter based on a preset priority from a plurality of communication parameters that can be supported by the communication device of the transmission destination of the optical signal transmitted by the signal transmitting means. The transmitting device according to Appendix 1, wherein the information is transmitted as information of the second communication parameter.

(Appendix 3)
Further provided is a combiner means for multiplexing the optical signal output by the signal transmitting means and the optical signal output by the parameter transmitting means for transmitting information of the second communication parameter and transmitting the optical signal to the transmission line. The transmitter according to Appendix 1 or 2, characterized in that.

(Appendix 4)
The parameter transmitting means is described in Appendix 1, wherein the signal transmitting means modulates a main signal transmitted based on the first communication parameter and transmits information of the second communication parameter. Transmitter.

(Appendix 5)
The parameter transmitting means is characterized in that the information of the second communication parameter is transmitted by adding the information of the second communication parameter to a part of the frame transmitted from the signal transmitting means as the optical signal. The transmitter according to Appendix 1.

(Appendix 6)
When the transmission control means receives a response indicating that communication is possible based on the second communication parameter from the transmission destination of the information of the second communication parameter, the signal transmission means receives the optical signal. The transmission device according to any one of Supplementary note 1 to 5, wherein the transmission device is controlled so as to transmit the signal based on the second communication parameter.

(Appendix 7)
Further provided with a receiving means for receiving the second optical signal via the second transmission line,
When the parameter transmission means transmits the information of the second communication parameter, the transmission control means receives a response from the transmission destination indicating that communication is possible based on the second communication parameter. The transmitting device according to any one of Supplementary note 1 to 7, wherein the receiving means controls to receive the optical signal based on the second communication parameter.

(Appendix 8)
A signal receiving means that receives an optical signal via a transmission line,
A parameter detecting means for detecting information on a second communication parameter included in the optical signal received based on the first communication parameter, and a parameter detecting means.
A reception control means for controlling the signal receiving means to receive the optical signal based on the second communication parameter when the parameter detecting means detects the information of the second communication parameter.
A receiving device characterized by comprising.

(Appendix 9)
Further, a branching means for branching the optical signal input via the transmission line is provided.
The receiving device according to Appendix 8, wherein the optical signal branched by the branching means is input to the signal receiving means and the parameter detecting means, respectively.

(Appendix 10)
The parameter receiving means is characterized in that it detects the modulation applied to the main signal received by the signal receiving means based on the first communication parameter and extracts the information of the second communication parameter. The receiving device according to Appendix 8.

(Appendix 11)
The receiving device according to an appendix 8, wherein the parameter receiving means extracts information of the second communication parameter from a part of a frame received by the signal receiving means as a light recording signal.

(Appendix 12)
When the reception control means can communicate based on the received information of the second communication parameter, the reception control means can communicate with the source of the information of the second communication parameter based on the second communication parameter. The receiving device according to any one of Supplementary note 8 to 11, wherein a response indicating that there is is transmitted.

(Appendix 13)
The transmitter according to any one of Supplementary Notes 1 to 7 and
The receiving device according to any one of Supplementary note 8 to 12, and
Equipped with
The parameter transmitting means of the transmitting device transmits the information of the second communication parameter to the receiving device via the transmission path based on the first communication parameter.
The parameter detecting means of the receiving device receives information of the second communication parameter from the transmitting device via the transmission line when communicating based on the first communication parameter. A communication system characterized by.

(Appendix 14)
When the optical signal is transmitted via the transmission line based on the first communication parameter, the information of the second communication parameter is transmitted via the transmission line.
A communication method in which the optical signal is transmitted based on the second communication parameter after the information of the second communication parameter is transmitted.

(Appendix 15)
When the optical signal is received via the transmission line based on the first communication parameter, the information of the second communication parameter included in the optical signal is detected.
The communication method according to Appendix 14, wherein the optical signal is received based on the second communication parameter.

(Appendix 16)
The communication parameter is selected based on a preset priority from a plurality of communication parameters that can be supported by the communication device of the transmission destination of the optical signal to be transmitted, and is transmitted as information of the second communication parameter. The communication method according to Appendix 14 or 15, characterized in that.

(Appendix 17)
The communication method according to any one of Supplementary note 14 to 16, wherein the main signal to be transmitted based on the first communication parameter is modulated to transmit the information of the second communication parameter.

(Appendix 18)
The communication according to Appendix 17, characterized in that the modulation applied to the received main signal based on the first communication parameter is detected and the information of the second communication parameter is extracted. Method.

(Appendix 19)
The communication according to any one of Supplementary note 14 to 16, wherein the information of the second communication parameter is transmitted by adding the information of the second communication parameter to a part of the frame to be transmitted as the optical signal. Method.

(Appendix 20)
The communication method according to Appendix 19, wherein the information of the second communication parameter is extracted from a part of the frame received as the optical signal.

(Appendix 21)
When a response indicating that communication is possible based on the second communication parameter is received from the transmission destination of the information of the second communication parameter, the optical signal is transmitted based on the second communication parameter. The communication method according to any one of Supplementary note 14 to 16, wherein the communication method is performed.

(Appendix 22)
When communication is possible based on the received information of the second communication parameter, a response indicating that communication is possible based on the second communication parameter is sent to the source of the information of the second communication parameter. The communication method according to Appendix 21, wherein the transmission is performed.

1 Signal transmission means 2 Parameter transmission means 3 Transmission control means 6 Signal reception means 7 Parameter detection means 8 Reception control means 10 Transmission device 11 Input port 12 Client signal reception unit 13 Line signal transmission unit 14 Electro-optical conversion unit 15 Convergence unit 16 Transmission control unit 17 Parameter transmission unit 20 Receiver 21 Output port 22 Client signal transmission unit 23 Line signal reception unit 24 Opto-electric conversion unit 25 Branch unit 26 Reception control unit 27 Parameter reception unit 30 Transmission line 31 Transmission line 40 Transmission device 41 Input Port 42 Client signal receiver 43 Line signal transmitter 44 Electro-optical converter 45 Transmit control 46 Parameter transmitter 50 Receiver 51 Output port 52 Client signal transmitter 53 Line signal receiver 54 Optical-electric converter 55 Receive control 56 Parameter receiver 60 Transmitter 61 Input port 62 Client signal receiver 63 Line signal transmitter 64 Electrical optical converter 65 Transmission control unit 66 Parameter transmitter 70 Receiver 71 Output port 72 Client signal transmitter 73 Line signal receiver 74 Optical Electrical conversion unit 75 Reception control unit 76 Parameter reception unit 81 First communication device 82 Second communication device 91 First communication device 92 Second communication device 100 Communication device 101 Input port 102 Client signal reception unit 103 Line signal transmission 104 Electric optical conversion unit 105 Setting control unit 106 Parameter transmission / reception unit 111 Output port 112 Client signal transmission unit 113 Line signal reception unit 114 Optical electrical conversion unit 120 Communication device 121 Input port 122 Client signal reception unit 123 Line signal transmission unit 124 Electricity Optical conversion unit 125 Setting control unit 126 Parameter transmission / reception unit 131 Output port 132 Client signal transmission unit 133 Line signal reception unit 134 Optical electrical conversion unit 201 Optical output unit 202 First modulation unit 203 Second modulation unit

Claims (10)

A signal transmission means that transmits an optical signal via a transmission line,
When the signal transmitting means transmits the optical signal based on the first communication parameter, the parameter transmitting means for transmitting the information of the second communication parameter via the transmission path and the parameter transmitting means.
A transmission control means that controls the signal transmission means to transmit the optical signal based on the second communication parameter after transmitting the information of the second communication parameter.
Equipped with
Each of the first communication parameter and the second communication parameter includes a plurality of types of parameters.
The plurality of types of parameters include a frame format.
The first communication parameter is a communication parameter corresponding to a setting in which the transmission rate is lower than that of the second communication parameter and the optical signal is stably transmitted.
The second communication parameter includes an error correction method in which the transmission rate is higher and error correction is performed at a higher level than the first communication parameter.
A transmitter characterized by that. The parameter transmitting means selects the communication parameter from a plurality of communication parameters that can be supported by the communication device of the transmission destination of the optical signal transmitted by the signal transmitting means based on a preset priority. The transmission device according to claim 1, wherein the transmission is performed as information of the second communication parameter. The first aspect of the present invention is characterized in that the parameter transmitting means modulates a main signal transmitted by the signal transmitting means based on the first communication parameter to transmit information of the second communication parameter. The transmitter described. The parameter transmitting means is characterized in that the information of the second communication parameter is transmitted by adding the information of the second communication parameter to a part of the frame transmitted from the signal transmitting means as the optical signal. The transmitting device according to claim 1. When the transmission control means receives a response indicating that communication is possible based on the second communication parameter from the transmission destination of the information of the second communication parameter, the signal transmission means receives the optical signal. The transmission device according to any one of claims 1 to 4, wherein the transmission device is controlled so as to transmit the signal based on the second communication parameter. Further provided with a receiving means for receiving the second optical signal via the second transmission line,
When the parameter transmission means transmits the information of the second communication parameter, the transmission control means receives a response from the transmission destination indicating that communication is possible based on the second communication parameter. The transmitting device according to any one of claims 1 to 5, wherein the receiving means controls to receive the optical signal based on the second communication parameter. A signal receiving means that receives an optical signal via a transmission line,
A parameter detecting means for detecting information on a second communication parameter included in the optical signal received based on the first communication parameter, and a parameter detecting means.
A reception control means for controlling the signal receiving means to receive the optical signal based on the second communication parameter when the parameter detecting means detects the information of the second communication parameter.
Equipped with
Each of the first communication parameter and the second communication parameter includes a plurality of types of parameters.
The plurality of types of parameters include a frame format.
The first communication parameter is a communication parameter corresponding to a setting in which the transmission rate is lower than that of the second communication parameter and the optical signal is stably transmitted.
The second communication parameter includes an error correction method in which the transmission rate is higher and error correction is performed at a higher level than the first communication parameter.
A receiver characterized by that. When the reception control means can communicate based on the received information of the second communication parameter, the reception control means can communicate with the source of the information of the second communication parameter based on the second communication parameter. The receiving device according to claim 7, wherein a response indicating that there is is transmitted. The transmitter according to any one of claims 1 to 6 and
With the receiving device according to claim 7 or 8.
Equipped with
The parameter transmitting means of the transmitting device transmits the information of the second communication parameter to the receiving device via the transmission path based on the first communication parameter.
The parameter detecting means of the receiving device receives information of the second communication parameter from the transmitting device via the transmission line when communicating based on the first communication parameter. A communication system characterized by. When the optical signal is transmitted via the transmission line based on the first communication parameter, the information of the second communication parameter is transmitted via the transmission line.
A communication method in which the optical signal is transmitted based on the second communication parameter after the information of the second communication parameter is transmitted.
Each of the first communication parameter and the second communication parameter includes a plurality of types of parameters.
The plurality of types of parameters include a frame format.
The first communication parameter is a communication parameter corresponding to a setting in which the transmission rate is lower than that of the second communication parameter and the optical signal is stably transmitted.
The second communication parameter includes an error correction method in which the transmission rate is higher and error correction is performed at a higher level than the first communication parameter.
A communication method characterized by that.

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