JP2006186760A - Optical transmission device, client interface device, optical transmission system, and optical transmission method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To communicate information on supervisory control etc., other than information carried by the main communication of an optical transmission system more efficiently by a simpler constitution by using a more inexpensive optical transmission device. <P>SOLUTION: In a node device 2a connected to a ring type wavelength multiplex transmission system, a supervisory control section 13a generates supervisory control information and converts it into an electric signal and an intensity modulation section 16a imposes intensity modulation on an optical signal received from a node device 2a with the electric signal and transmits the modulated signal to the node device 2b. In the node device 2b, a photoelectric conversion section 12b converts the received optical signal into an electric signal, a supervisory control section 13b converts the converted electric signal into the supervisory control information and uses it, and an intensity demodulation section 14b imposes intensity modulation on the received optical signal with the converted electric signal. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an optical transmission device, a client interface device, an optical transmission system, and an optical transmission method. In particular, the present invention relates to a method for realizing supervisory control in a ring-type wavelength division multiplexing transmission system.

In the conventional supervisory control method of a ring-type wavelength division multiplexing transmission system, a supervisory control signal is transmitted by using a light source for a supervisory control signal in addition to the light source of the optical main signal (see, for example, Patent Document 1). ). Further, in the supervisory control system of other ring-type wavelength division multiplexing transmission systems, a supervisory control signal is transmitted to the entire system by applying a supervisory control modulation to the wavelength multiplexed optical main signal (for example, , See Patent Document 2).
JP 2003-218798 A JP 2003-32190 A

  In the supervisory control method of the first ring-type wavelength division multiplexing transmission system, each node device (mainly a client device is connected) to transmit the supervisory control signal at a wavelength different from the wavelength-multiplexed optical main signal. At least one light source for monitoring control for each of the clockwise and counterclockwise directions is required for the relay device (mainly an optical transmission device not connected to the client device). In addition, it is necessary to terminate the signal light for each section.

  Further, as a configuration that does not use a light source for supervisory control, in the supervisory control method of the second ring-type wavelength division multiplexing transmission system, the strength is such that communication with respect to the wavelength-multiplexed optical main signal is not hindered. Supervisory control is performed by applying modulation. In this configuration, since the supervisory control signal is relayed and transmitted by the optical amplifying repeater, the supervisory control modulation is applied to the main signal of the entire system. Therefore, the optical main signal in the section that is not subject to supervisory control is also modulated for supervisory control, and the modulated signal for supervisory control need not be communicated (transmitted to a relay station that is not subject to supervisory control). Is done. Further, in order to perform monitoring control for a plurality of transmission paths or transmission devices, it is necessary to perform communication control by time division in the entire system.

  Thus, conventionally, in order to perform supervisory control of the optical transmission system, it is necessary to provide a dedicated light source for supervisory control, and an expensive optical transmission device has to be used. In addition, it is necessary to transmit a supervisory control signal to a relay station that does not need to communicate, or to perform communication control by time division throughout the system, and low-efficiency supervisory control is performed in an optical transmission system with a complicated configuration. It was.

  An object of the present invention is to perform communication of information other than information carried in main communication of an optical transmission system, such as supervisory control, with a simpler configuration and more efficiently using a cheaper optical transmission apparatus. And

The optical transmission device of the present invention is
In each optical transmission device of a plurality of optical transmission devices that are connected in a ring shape and transmit optical signals,
An optical reception interface unit that receives an optical signal whose intensity is modulated by an electrical signal converted from the first information from a previous optical transmission device; and
A branching unit that branches the optical signal received by the optical reception interface unit in at least two directions;
A photoelectric conversion unit that converts an optical signal in one direction branched by the branching unit into an electrical signal according to the intensity of the optical signal; and
An intensity demodulating unit that demodulates and outputs an optical signal in the other direction branched by the branching unit with an electrical signal output by the photoelectric conversion unit;
An information utilization unit that converts and uses the electrical signal output by the photoelectric conversion unit into the first information;
An information generator that generates second information, converts the second information into an electrical signal, and outputs the electrical signal;
An intensity modulator that modulates the intensity of the optical signal output from the intensity demodulator by the electrical signal output from the information generator;
And an optical transmission interface unit that transmits the optical signal output from the intensity modulation unit to the next optical transmission device.

  In the present invention, each of a plurality of optical transmission devices connected in a ring shape in an optical transmission system generates information and converts it into an electrical signal, and the optical signal received from the previous optical transmission device by the electrical signal. The signal is intensity-modulated and transmitted to the next optical transmission device. The next optical transmission device converts the received optical signal into an electrical signal, converts the converted electrical signal into information, uses it, and receives it. By demodulating the intensity with the electrical signal converted from the optical signal, communication of information other than the information carried in the main communication of the optical transmission system, such as supervisory control, can be performed more easily using a cheaper optical transmission device. With the configuration, it is possible to perform more efficiently.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  In each of the following embodiments, the ring type wavelength division multiplexing transmission system is an example of an optical transmission system. The node device is a kind of optical transmission device connected to the ring type wavelength division multiplexing transmission system, and similarly communicates with other node devices connected to the ring type wavelength division multiplexing transmission system. A client device (hereinafter referred to as a client) is, for example, an SDH (Synchronous Digital Hierarchy) client, is connected to a node device via a client interface device, and communicates with another client connected to another node device. A relay device (also referred to as a relay station) is a kind of optical transmission device connected to a ring-type wavelength division multiplexing transmission system, is connected between a plurality of node devices, and relays communication between node devices.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing a configuration of a ring type wavelength division multiplexing transmission system according to the present embodiment.

  In FIG. 1, the ring-type wavelength division multiplexing transmission system includes a transmission line 1, a node device 2a, a transmission line 19, and a node device 2b. Although this embodiment has been described using a ring-type wavelength division multiplexing transmission system having two optical transmission devices, that is, the node device 2a and the node device 2b, for convenience, it is configured by three or more optical transmission devices. It can also be applied to an optical transmission system. In addition, for convenience, this embodiment describes a ring-type wavelength division multiplexing transmission system configured only by the active system, but can also be applied to an optical transmission system configured by an active system and a standby system.

  The client interface device 3 on the transmission side converts an optical signal from the client into an electrical signal by the photoelectric converter 5a, and gives an FEC (Forward Error Correction) code to the electrical signal by the FEC encoder unit 10, The light is converted into an optical signal by the optical converter 6a. This optical signal is input to the wavelength multiplexing (wavelength multiplexing) port of the multiplexing / demultiplexing unit 9a of the node device 2a. Further, the client interface device 4 on the receiving side converts the optical signal from the wavelength demultiplexing (wavelength separation) port of the multiplexing / demultiplexing unit 9b of the node device 2b into an electrical signal by the photoelectric converter 5b, and this electrical signal Then, the FEC decoder 11 removes the FEC code, and the electro-optical converter 6b converts it into an optical signal. This optical signal is transmitted to the client side. Here, for convenience, the optical signal from the client side is described as one wave, but the same applies when there are a plurality of optical signals from the client side.

  The node device 2a inputs the optical signal wavelength-multiplexed by the multiplexing / demultiplexing unit 9a to the intensity modulating unit 16a. The monitoring control unit 13a measures the quality of the transmission line 1, monitors the operation status of the node device 2a, collects information on the client interface device 3, and performs remote operation from a device that performs network monitoring. By receiving an instruction or the like, supervisory control is performed and information for supervisory control is converted into an electrical signal. By driving the intensity modulator 16a with this electric signal, the wavelength-multiplexed optical signal is further subjected to intensity modulation. Then, the intensity-modulated optical signal is input to the optical amplifier 8a, amplified so as to obtain a desired optical output, and output to the transmission line 19 via the optical transmission interface unit 23a.

  The intensity modulation unit 16a is implemented as an optical variable attenuator (OVA) and is driven by an electric signal representing a logical value (0/1), thereby converting the gain of the input optical signal into a logical value. It can be changed according to the intensity modulation. In addition to the optical variable attenuator, the intensity modulation unit 16a is an optical attenuator such as OAM (Optical Acoustic Modulator), or an EDFA (Erbium-Doped Fiber Amplifier), SOA (Semiconductor Amplifier Amplifier, LOA, etc.). It may be implemented as an optical amplifier. Further, the intensity modulation unit 16a and the optical amplifier 8a may be implemented by a single optical amplifier.

  The wavelength multiplexed signal transmitted through the transmission line 19 is input to the node device 2b via the optical reception interface unit 21b, and branched in two directions by the branching unit 15b. The node device 2b inputs an optical signal in one direction to the intensity demodulator 14b, and inputs an optical signal in the other direction to the photoelectric converter 12b to convert it into an electric signal.

  The photoelectric conversion unit 12b is mounted as a combination of PD (Photo Detector) and LPF (Low Pass Filter), for example, and extracts an intensity modulation component for monitoring control of the optical signal wavelength-multiplexed by the node device 2a. In this embodiment, the main signal of the wavelength-multiplexed optical signal (signal transmitted / received in the main communication of the optical transmission system) is transmitted at, for example, 10 Gbps (gigabit / second), and the monitoring control signal (main communication of the optical transmission system) An example of a signal transmitted / received other than the above is transmitted at, for example, 10 Mbps (megabit / second). In this case, since the transmission rate of the monitoring control signal is lower than the transmission rate of the main signal, the frequency of the carrier wave is also low, and the LPF plays a role of removing high frequency components not including the monitoring control signal.

  A monitoring control signal output from the photoelectric conversion unit 12b is input to the monitoring control unit 13b and converted into monitoring control information, whereby the monitoring control information is transmitted from the node device 2a to the node device 2b. This monitoring control information is used by the monitoring control unit 13b. The monitoring control information includes transmission path quality information, node device operation information, client interface device information, command information for remote operation, and the like, based on this information, the monitoring control unit 13b allows the node device 2b and other devices. To control. Further, the monitoring control unit 13b may notify this information to a device that performs network monitoring.

  The node device 2b drives the intensity demodulator 14b with an electrical signal obtained by inverting the logical value of the supervisory control signal output from the photoelectric converter 12b, thereby transmitting the optical signal transmitted through the transmission line 19. Only the intensity modulation component is removed. Then, the optical signal from which the intensity modulation component for monitoring and control is removed by the intensity demodulating unit 14b is amplified by the optical amplifier 7b, compensated for the transmission path loss, and input to the multiplexing / demultiplexing unit 9b.

  Similar to the intensity modulator 16a, the intensity demodulator 14b is implemented as an optical attenuator such as an optical variable attenuator (OVA) or OAM, or an optical amplifier such as EDFA, SOA, or LOA, and has a logical value (0/1). By being driven by an electric signal obtained by inverting the signal, the gain of the input optical signal can be changed according to the logical value opposite to that in the intensity modulation, and the intensity can be demodulated.

  The node device 2b transmits, to the client interface device 4, a signal addressed to a client connected to the node device 2b via the client interface device 4 on the receiving side among the optical signals separated by the multiplexing / demultiplexing unit 9b. . Other signals are wavelength-multiplexed by the multiplexing / demultiplexing unit 9b, and are transmitted to the transmission line 1 through the intensity modulation unit 16b, the optical amplifier 8b, and the optical transmission interface unit 23b in the same manner as the multiplexing / demultiplexing unit 9a of the node device 2a described above. Is output. The process in which the node device 2a receives the optical signal output to the transmission line 1 is the same as that of the node device 2b.

  As described above, in the present embodiment, each of a plurality of node devices connected to the ring-type wavelength division multiplexing transmission system generates monitoring control information and converts it into an electrical signal. The optical signal received from the node device is intensity-modulated and transmitted to the next node device. The next node device converts the received optical signal into an electric signal, and converts the converted electric signal into monitoring control information for use. In addition, by demodulating the intensity of the received optical signal with the converted electric signal, the monitoring control information can be communicated more efficiently with a simpler configuration using a cheaper node device. Become.

Embodiment 2. FIG.
FIG. 2 is a block diagram showing a configuration of the ring-type wavelength division multiplexing system according to the present embodiment.

  In FIG. 2, the ring-type wavelength division multiplexing transmission system includes a transmission path 1, a relay apparatus 20a, a transmission path 19, and a relay apparatus 20b. Although this embodiment has been described using a ring-type wavelength division multiplexing transmission system having two optical transmission devices, ie, a relay device 20a and a relay device 20b, for convenience, it is configured by three or more optical transmission devices. It can also be applied to an optical transmission system. In addition, for convenience, this embodiment describes a ring-type wavelength division multiplexing transmission system configured only by the active system, but can also be applied to an optical transmission system configured by an active system and a standby system.

  The wavelength multiplexed signal transmitted through the transmission line 1 is input to the repeater 20a via the optical reception interface unit 21a, and branched in two directions by the branch unit 15a. The relay device 20a inputs an optical signal in one direction to the intensity modulation / demodulation unit 22a, and inputs an optical signal in the other direction to the photoelectric conversion unit 12a. At this stage, it is assumed that the wavelength multiplexed signal is not intensity-modulated for monitoring and control, and no electrical signal is output from the photoelectric conversion unit 12a to the adder circuit 18a.

  The supervisory control unit 13a measures the quality of the transmission line 1, monitors the operation status of the relay device 20a, and receives a command for remote operation from a device that performs network monitoring. The information for monitoring control is converted into an electrical signal. The supervisory controller 13a outputs this electric signal to the adder circuit 18a, and drives the intensity modulator / demodulator 22a with the electric signal from the adder circuit 18a, thereby further applying intensity modulation to the wavelength-multiplexed optical signal. Then, the intensity-modulated optical signal is input to the optical amplifier 8a, amplified so as to obtain a desired optical output, and output to the transmission line 19 via the optical transmission interface unit 23a.

  The intensity modulation / demodulation unit 22a is implemented as an optical attenuator such as an optical variable attenuator (OVA) or OAM, or an optical amplifier such as EDFA, SOA, or LOA, and is input by being driven by an electric signal representing a logical value. The intensity of the optical signal can be modulated by changing the gain of the optical signal in accordance with the logical value.

  The wavelength multiplexed signal transmitted through the transmission line 19 is input to the repeater 20b via the optical reception interface unit 21b, and branched in two directions by the branching unit 15b. The relay device 20b inputs an optical signal in one direction to the intensity modulation / demodulation unit 22b, and inputs an optical signal in the other direction to the photoelectric conversion unit 12b to convert it into an electric signal.

  The photoelectric conversion unit 12b is implemented as a combination of PD and LPF, for example, and extracts an intensity modulation component for monitoring control of the optical signal wavelength-multiplexed by the relay device 20a. The monitoring control signal output from the photoelectric conversion unit 12b is input to the monitoring control unit 13b and converted into monitoring control information, whereby the monitoring control information is transmitted from the relay device 20a to the relay device 20b. This monitoring control information is used by the monitoring control unit 13b. The monitoring control information includes transmission path quality information, relay device operation information, command information for remote operation, and the like, and the monitoring control unit 13b controls the relay device 20b and other devices based on this information. Further, the monitoring control unit 13b may notify this information to a device that performs network monitoring.

  The relay device 20b has an electrical signal obtained by inverting the logical value of the monitoring control signal output from the photoelectric conversion unit 12b, and the monitoring signal transmitted from the relay device 20b output from the monitoring control unit 13b to the relay device 20a. A control signal or a monitor control signal uniquely generated by the monitor control unit 13b is input to the adder circuit 18b. Then, the intensity modulation / demodulation unit 22b is driven by the electric signal output by the addition circuit 18b adding the two signals, thereby removing the intensity modulation component of the optical signal transmitted through the transmission path 19, and The optical signal is subjected to intensity modulation for monitoring control by the monitoring control unit 13b. Subsequently, the wavelength division multiplexed signal output from the intensity modulation / demodulation unit 22b and subjected to the intensity modulation for monitoring control is amplified to a desired optical output by the optical amplifier 7b, and the transmission line 1 is transmitted via the optical transmission interface unit 23b. Output to. The process in which the relay device 20a receives the optical signal output to the transmission line 1 is the same as that of the relay device 20b.

  Similar to the intensity modulation / demodulation unit 22a, the intensity modulation / demodulation unit 22b is implemented as an optical attenuator such as an optical variable attenuator (OVA) or OAM, or an optical amplifier such as EDFA, SOA, or LOA. , The intensity of the input optical signal can be modulated and demodulated.

  As described above, in the present embodiment, each of a plurality of relay apparatuses connected to the ring-type wavelength division multiplexing transmission system generates or receives monitoring control information and converts it into an electrical signal. The optical signal received from the previous repeater is intensity-modulated and transmitted to the next repeater. The next repeater converts the received optical signal into an electrical signal, and converts the converted electrical signal into monitoring control information. In addition, the intensity of the received optical signal is demodulated by the converted electrical signal, so that the monitoring control information can be communicated more efficiently with a simpler configuration using a cheaper relay device. It becomes possible.

Embodiment 3 FIG.
FIG. 3 is a block diagram showing the configuration of the ring-type wavelength division multiplexing system according to the present embodiment.

  In the first embodiment, the intensity modulation for monitoring control is applied to the wavelength-multiplexed optical signal. However, in this embodiment, the monitoring control of the client interface device 3 on the transmission side is performed as shown in FIG. The intensity modulation unit 16a is driven by the electrical signal converted from the monitoring control information by the unit 13a, and intensity modulation for monitoring control is performed for each wave of the optical signal from the client side. The optical signal multiplexed by the multiplexing / demultiplexing unit 9a of the node device 2a is demultiplexed by the multiplexing / demultiplexing unit 9b of the node device 2b and input to the client interface device 4 on the receiving side. The input optical signal is branched in two directions by the branching unit 15b, and the optical signal in one direction is converted into an electrical signal by the photoelectric conversion unit 12b. Using this electrical signal, the supervisory controller 13b acquires supervisory control information, and the intensity demodulator 14b transmits an optical signal from which the intensity modulation component for supervisory control is removed to the client side. Here, the client connected to the client interface device 3 on the transmission side and the client connected to the client interface device 4 on the reception side are different devices.

  The processing in which the client interface device 3 on the transmission side performs intensity modulation for monitoring control on the optical signal is the same as that of the node device 2a of the first embodiment. Further, the processing of the receiving side client interface device 4 performing the optical signal intensity demodulation is the same as that of the node device 2b of the first embodiment.

  As described above, in this embodiment, the client interface device connected between the node device connected to the ring-type wavelength division multiplex transmission system and the client generates monitoring control information and converts it into an electrical signal. The optical signal received from the client is intensity-modulated by the electrical signal and transmitted to the node device, and the client interface device connected between another node device and another client receives it via the other node device. By converting the converted optical signal into an electrical signal, converting the converted electrical signal into monitoring control information and using it, and by demodulating the received optical signal with the converted electrical signal and transmitting it to another client The monitoring control information that normally needs to be inserted into the FEC can be transmitted and received without using the FEC. Accordingly, monitoring control information can be communicated even in communication between client interface devices that do not use FEC, and the transfer amount of monitoring control information can be increased because the size of the FEC is not limited.

  A single ring-type wavelength division multiplexing transmission system can be configured by combining a plurality of node devices, relay devices, and client interface devices described in the first to third embodiments.

  In the first to third embodiments, information transmitted or received by each optical transmission device or client interface device has been described as monitoring control information. However, any other information may be used.

The ring-type wavelength multiplex transmission system described in the first to third embodiments is as follows.
In a ring network composed of a plurality of wavelength multiplexing node devices, a variable gain conversion unit and a modulation control unit that modulates the intensity of the wavelength division multiplexed optical signal with monitoring control information in the monitoring control unit, an optoelectric conversion unit, and a variable gain conversion unit A monitoring unit that reads the monitoring control information from the intensity-modulated wavelength multiplexed optical signal and cancels the intensity modulation; a multiplexing / demultiplexing unit that performs wavelength demultiplexing; and an optical amplification that collectively amplifies the wavelength multiplexed signal light It comprises an inter-node device monitoring control communication means comprising a unit.

The ring-type wavelength division multiplexing transmission system is
In a ring network composed of a plurality of relay devices, a signal for reading monitoring control information from a wavelength-multiplexed optical signal whose intensity is modulated in the photoelectric conversion unit and the monitoring control unit, and canceling the intensity modulation, and the next-stage relay device Between the relay devices comprising an adding circuit unit for adding monitoring control information to drive the variable gain conversion unit, a multiplexing / demultiplexing unit for performing wavelength multiplexing and demultiplexing, and an optical amplifying unit for amplifying the wavelength multiplexed signal light collectively Control communication means is provided.

The ring-type wavelength division multiplexing transmission system is
In a ring network composed of a plurality of wavelength multiplexing node devices, a variable gain conversion unit and a client interface device unit that performs intensity modulation on the optical signal of the monitoring control information in the monitoring control unit, an optoelectric conversion unit, and a variable gain conversion unit The monitoring control information in the supervisory control unit from the optical signal whose intensity is modulated and cancel the intensity modulation, the multiplexing / demultiplexing unit for performing wavelength multiplexing and demultiplexing, and the optical amplification for collectively amplifying the wavelength multiplexed signal light It is characterized by comprising a monitoring control communication means between client interface devices comprising a unit.

The ring-type wavelength division multiplexing transmission system is
The inter-node device monitoring control communication means and the client interface device monitoring control communication means are provided.

The ring-type wavelength division multiplexing transmission system is
The inter-relay device monitoring control communication means, and the client interface device monitoring control communication means are provided.

The ring-type wavelength division multiplexing transmission system is
The inter-node device monitoring control communication means, the inter-relay device monitoring control communication means, and the inter-client interface device monitoring control communication means.

1 is a block diagram showing a configuration of an optical transmission system according to Embodiment 1. FIG. FIG. 3 is a block diagram illustrating a configuration of an optical transmission system according to a second embodiment. FIG. 4 is a block diagram illustrating a configuration of an optical transmission system according to a third embodiment.

Explanation of symbols

  1, 19 Transmission path, 2 node device, 3, 4 Client interface device, 5 Photoelectric converter, 6 Electrooptical converter, 7, 8, 17 Optical amplifier, 9 Multiplexing / demultiplexing unit, 10 FEC encoder unit, 11 FEC Decoder unit, 12 photoelectric conversion unit, 13 monitoring control unit, 14 intensity demodulation unit, 15 branching unit, 16 intensity modulation unit, 18 addition circuit, 20 relay device, 21 optical reception interface unit, 22 intensity modulation / demodulation unit, 23 optical transmission Interface part.

Claims (13)

In each optical transmission device of a plurality of optical transmission devices that are connected in a ring shape and transmit optical signals,
An optical reception interface unit that receives an optical signal whose intensity is modulated by an electrical signal converted from the first information from a previous optical transmission device; and
A branching unit that branches the optical signal received by the optical reception interface unit in at least two directions;
A photoelectric conversion unit that converts an optical signal in one direction branched by the branching unit into an electrical signal according to the intensity of the optical signal; and
An intensity demodulating unit that demodulates and outputs an optical signal in the other direction branched by the branching unit with an electrical signal output by the photoelectric conversion unit;
An information utilization unit that converts and uses the electrical signal output by the photoelectric conversion unit into the first information;
An information generator that generates second information, converts the second information into an electrical signal, and outputs the electrical signal;
An intensity modulator that modulates the intensity of the optical signal output from the intensity demodulator by the electrical signal output from the information generator;
An optical transmission device comprising: an optical transmission interface unit that transmits an optical signal output from the intensity modulation unit to a next optical transmission device. The optical transmission device further includes:
The optical signal output from the intensity demodulating unit is wavelength-separated, and includes a multiplexing / demultiplexing unit that wavelength-multiplexes and outputs the wavelength-separated optical signal and the optical signal input from the external device,
The intensity modulator is
2. The optical transmission apparatus according to claim 1, wherein the optical signal output from the multiplexing / demultiplexing unit is output after being intensity-modulated by the electrical signal output from the information generating unit. The optical transmission device further includes:
The optical signal output from the intensity demodulating unit is wavelength-separated, a part of the wavelength-separated optical signal is output to an external device, and another optical signal that has been wavelength-separated is wavelength-division multiplexed and output.
The intensity modulator is
2. The optical transmission apparatus according to claim 1, wherein the optical signal output from the multiplexing / demultiplexing unit is output after being intensity-modulated by the electrical signal output from the information generating unit.   The optical transmission apparatus according to claim 1, wherein the intensity demodulator and the intensity modulator are optical variable attenuators that attenuate optical signals. The optical transmission device further includes:
A calculation unit that calculates and outputs the electrical signal output from the photoelectric conversion unit and the electrical signal output from the information generation unit;
Instead of the intensity demodulating unit and the intensity modulating unit, the intensity of the optical signal in the other direction branched by the branching unit is changed by the electrical signal output from the computing unit, and an optical signal with a changed intensity is output. An intensity modulation / demodulation unit,
The optical transmission interface unit
The optical transmission device according to claim 1, wherein the optical signal output from the intensity modulation / demodulation unit is transmitted to a next optical transmission device.   The optical transmission device according to claim 5, wherein the arithmetic unit is an addition circuit that adds a plurality of electrical signals.   The optical transmission apparatus according to claim 5, wherein the intensity modulation / demodulation unit is an optical variable attenuator that attenuates an optical signal. The information generator is
The optical transmission device according to claim 1, wherein supervisory control of the optical transmission device and the outside is performed, and supervisory control information related to the supervisory control is generated as the second information. The information utilization unit
9. The optical transmission device according to claim 1, wherein supervisory control information related to supervisory control performed by the previous optical transmission device is used as the first information. In a client interface device connected between one of a plurality of optical transmission devices connected in a ring shape and transmitting an optical signal and a client device transmitting an optical signal,
An optical reception interface unit for receiving an optical signal from a client device;
An information generating unit that generates information, converts the information into an electrical signal, and outputs the electrical signal;
An intensity modulation unit that modulates the intensity of the optical signal received by the optical reception interface unit with the electrical signal output by the information generation unit; and
A client interface device comprising: an optical transmission interface unit that transmits an optical signal output from the intensity modulation unit to an optical transmission device. In a client interface device connected between one of a plurality of optical transmission devices connected in a ring shape and transmitting an optical signal and a client device receiving an optical signal,
An optical reception interface unit that receives an optical signal intensity-modulated by an electrical signal converted from information from an optical transmission device; and
A branching unit that branches the optical signal received by the optical reception interface unit in at least two directions;
A photoelectric conversion unit that converts an optical signal in one direction branched by the branching unit into an electrical signal according to the intensity of the optical signal; and
An intensity demodulating unit that demodulates and outputs an optical signal in the other direction branched by the branching unit with an electrical signal output by the photoelectric conversion unit;
An information utilization unit that converts and uses the electrical signal output by the photoelectric conversion unit;
A client interface device comprising: an optical transmission interface unit configured to transmit an optical signal output from the intensity demodulation unit to the client device. In an optical transmission system that connects a plurality of optical transmission devices that transmit optical signals in a ring shape,
Connecting the first optical transmission device and the second optical transmission device via a transmission line;
The first optical transmission device is:
An information generating unit that generates information, converts the information into an electrical signal, and outputs the electrical signal;
An intensity modulator that modulates the intensity of the optical signal with the electrical signal output from the information generator, and outputs the optical signal;
An optical transmission interface unit that transmits the optical signal output by the intensity modulation unit to the transmission path;
The second optical transmission device is:
An optical reception interface unit that receives an optical signal transmitted by the optical transmission interface unit from the transmission path;
A branching unit that branches the optical signal received by the optical reception interface unit in at least two directions;
A photoelectric conversion unit that converts an optical signal in one direction branched by the branching unit into an electrical signal according to the intensity of the optical signal; and
An information utilization unit that converts and uses the electrical signal output by the photoelectric conversion unit;
An optical transmission system comprising: an intensity demodulating unit that demodulates an optical signal in the other direction branched by the branching unit with an electrical signal output from the photoelectric converting unit and outputs the demodulated signal. In an optical transmission method using an optical transmission system in which a plurality of optical transmission devices that transmit optical signals are connected in a ring shape,
Connecting the first optical transmission device and the second optical transmission device via a transmission line;
The first optical transmission device is
An information generation step of generating information, converting the information into an electrical signal, and outputting the electrical signal;
An intensity modulation step of intensity-modulating and outputting an optical signal with the electrical signal output in the information generation step;
An optical transmission step of transmitting the optical signal output in the intensity modulation step to the transmission path;
The second optical transmission device is
An optical reception step of receiving the optical signal transmitted from the first optical transmission device in the optical transmission step from the transmission path;
A branching step of branching the optical signal received in the optical receiving step in at least two directions;
A photoelectric conversion step of converting the optical signal in one direction branched in the branching step into an electrical signal according to the intensity of the optical signal and outputting the electrical signal;
An information utilization step of converting and using the electrical signal output in the photoelectric conversion step;
An optical power transmission method comprising: an intensity demodulating step of demodulating and outputting an optical signal in the other direction branched in the branching step with an electric signal output in the photoelectric conversion step.

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