JP2020053822A - Optical transmission device and control method - Google Patents

Abstract

To provide an optical transmission device capable of detecting a change in a state of an optical transceiver without delay.SOLUTION: An optical transmission device 1 includes connection means 2, power supply means 3, acquisition means 4 and monitor means 5. The connection means 2 includes a connector for connecting an optical transceiver and connecting the optical transceiver through the connector. The power supply means 3 supplies electric power to the transceiver through the connector. The acquisition means 4 acquires information of electric power to be supplied to the transceiver through the connector. The monitor means 5 monitors a state of the optical transceiver on the basis of the information of power.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an optical communication technology, and more particularly, to a technology for monitoring a state of an optical transceiver.

  2. Description of the Related Art Pluggable type optical transceivers are often used in optical transmission devices housed in data centers and office buildings. In order to operate the optical communication system stably, it is necessary to monitor the operation state of the optical transceiver connected to the optical transmission device. Monitoring of the operation state of the pluggable optical transceiver is performed, for example, by communication between the optical transceiver and the optical transmission device via a control communication bus. However, when the number of mounted optical transceivers increases, congestion occurs in the communication bus, and it may take time to monitor the operation state. Therefore, it is necessary to suppress the amount of data communication via the communication bus as much as possible. Therefore, it is desirable to have a technique that can suppress the amount of communication via the communication bus and monitor the state of the optical transceiver. As a technique for monitoring the optical transceiver while suppressing the communication amount of the communication bus, for example, a technique as disclosed in Patent Document 1 is disclosed.

  Patent Literature 1 relates to a pluggable optical transceiver having a function of storing monitoring information. The optical transceiver of Patent Literature 1 has a correspondence table indicating correspondence between a failure cause estimated in a device and a monitoring result, and stores the estimated failure cause in a memory. In Patent Document 1, it is stated that a cause of a failure can be investigated in a short time by an operator reading data of the cause of the failure from the memory.

JP 2014-107676 A

  However, the technique of Patent Document 1 is not sufficient in the following points. In Patent Literature 1, data on a cause of failure stored in a memory of an optical transceiver is read at the time of analysis. Therefore, the optical transmission apparatus cannot immediately recognize the change in the state when the state changes due to an abnormality or the like in the optical transceiver. Therefore, the technique of Patent Document 1 is insufficient as a technique for grasping a change in the state of the optical transceiver without delay.

  An object of the present invention is to provide an optical transmission device capable of detecting a change in the state of an optical transceiver without delay in order to solve the above-mentioned problems.

  In order to solve the above-described problem, an optical transmission device according to the present invention includes a connection unit, a power supply unit, an acquisition unit, and a control unit. The connection means has a connector for connecting the optical transceiver, and connects the optical transceiver via the connector. The power supply means supplies power to the optical transceiver via the connector. The obtaining means obtains information on power supplied to the optical transceiver via the connector. The monitoring means monitors the state of the optical transceiver based on the power information.

  According to the control method of the present invention, an optical transceiver is connected to a connector to which the optical transceiver is connected via a connector. The control method of the present invention supplies power to an optical transceiver via a connector. According to the control method of the present invention, information on power supplied to an optical transceiver via a connector is obtained. The control method of the present invention monitors the state of an optical transceiver based on information on power.

  According to the present invention, a change in the state of the optical transceiver can be detected without delay.

It is a figure showing the outline of composition of a 1st embodiment of the present invention. It is a figure showing the outline of composition of a 2nd embodiment of the present invention. It is a figure showing composition of a control part of a 2nd embodiment of the present invention. It is a figure showing the outline of composition of a 3rd embodiment of the present invention. It is a figure showing the composition of the control part of a 3rd embodiment of the present invention. It is a figure showing the outline of composition of a 4th embodiment of the present invention. It is a figure showing the composition of the control part of a 4th embodiment of the present invention.

(First embodiment)
A 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 optical transmission device of the present embodiment. The optical transmission device 1 of the present embodiment includes a connection unit 2, a power supply unit 3, an acquisition unit 4, and a monitoring unit 5. The connection means 2 has a connector for connecting the optical transceiver, and connects the optical transceiver via the connector. Power supply means 3 supplies power to the optical transceiver via the connector. Acquisition means 4 acquires information on the power supplied to the optical transceiver via the connector. The monitoring unit 5 monitors the state of the optical transceiver based on the information on the power.

  In the optical transmission device 1 according to the present embodiment, the acquisition unit 4 acquires information on the power supplied from the power supply unit 3 to the optical transceiver connected to the connection unit 2. In addition, the optical transmission device 1 of the present embodiment monitors the state of the optical transceiver based on the power information acquired by the acquisition unit 4 in the monitoring unit 5. As described above, by monitoring the optical transceiver based on the power supplied to the optical transceiver, the optical transmission device 1 of the present embodiment detects a change in the state of the optical transceiver based on a change in the supplied power. can do. Further, by monitoring the optical transceiver based on the power supplied to the optical transceiver, the speed of the communication bus or the like does not become rate-limiting. Therefore, when the state of the connected optical transceiver changes, the optical transmission device 1 of the present embodiment can detect the change in state without requiring time based on the change in power. Therefore, the optical transmission device 1 of the present embodiment can detect a change in the state of the optical transceiver without delay.

(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 optical transmission device 10 of the present embodiment. The optical transmission device 10 of the present embodiment is a communication device that includes a plurality of optical transceivers and transmits and receives a wavelength multiplexed signal to and from another optical transmission device via an optical communication network.

  The optical transmission device 10 of the present embodiment includes an optical transceiver 11, a current measuring unit 12, a control unit 13, and a power supply unit 14. The optical transceiver 11 includes N optical transceivers 11-1 to 11-N (N is a positive integer). Each optical transceiver 11 is a pluggable optical transceiver connected to the optical transmission device via the connector 100. Further, N current measuring units 12 are provided from the current measuring unit 12-1 to the current measuring unit 12-N so as to correspond to the optical transceiver 11, respectively.

  The optical transceiver 11 has a function of transmitting and receiving an optical signal. The optical transceiver 11 includes a light source, a modulator, a photodiode, a signal processing circuit, and the like, and operates based on power supplied from the power supply unit 14. The optical transceiver 11 transmits and receives an optical signal based on a signal input and output from the optical transmission device 10.

  The current measuring unit 12 has a function of acquiring a current value supplied to each optical transceiver 11. The current measuring units 12 are provided on power supply lines that supply power from the power supply unit 14 to the optical transceivers 11, respectively. The current measurement unit 12 measures a current flowing through the power supply line, and outputs a measurement result to the control unit 13. The function of the current measuring unit 12 of the present embodiment corresponds to the acquisition unit 4 of the first embodiment.

  The configuration of the control unit 13 will be described. FIG. 3 shows a configuration of the control unit 13 of the present embodiment. The control unit 13 of the present embodiment includes a power supply control unit 111 and a current value acquisition unit 112.

  The power control unit 111 controls the power unit 14 based on the operation state of the optical transceiver 11. The power control unit 111 determines the state of each optical transceiver 11 based on the measurement result of the current supplied to each optical transceiver 11 obtained via the current value obtaining unit 112.

  The power supply control unit 111 outputs to the power supply unit 14 a signal indicating that the supply of power is stopped when the current value supplied to the optical transceiver 11 does not satisfy a predetermined standard. When the current value does not satisfy the predetermined criterion, the power supply control unit 111 outputs a signal indicating that an abnormality has occurred in the optical transceiver 11 to a management system or the like connected to the optical transmission device 10. May be.

  The current value acquisition unit 112 acquires the measurement result of the current value of the current supplied from each current measurement unit 12 to each optical transceiver 11. Further, the function of the control unit 13 of the present embodiment corresponds to the monitoring unit 5 of the first embodiment.

  The control unit 13 is configured using, for example, a semiconductor device such as an FPGA (Field Programmable Gate Array). The control unit 13 may perform each process by executing a program in a general-purpose processor such as a CPU (Central Processing Unit).

  The power supply unit 14 supplies power to each optical transceiver 11 via a power supply line. Each optical transceiver 11 is connected to the power supply unit 14 in parallel. The power supply unit 14 supplies power to each optical transceiver 11 based on power supplied from the outside. In addition, the function of the power supply unit 14 of the present embodiment corresponds to the power supply unit 3 of the first embodiment.

  The connector 100 is provided as a connection unit for connecting the optical transceiver 11. The connector 100 has a signal line for inputting and outputting signals transmitted and received by the optical transceiver 11, a power supply line, a communication bus for inputting and outputting control signals, and the like. Further, the function of the connector 100 of the present embodiment corresponds to the connection means 2 of the first embodiment.

  The operation of the optical transmission device 10 according to the present embodiment will be described. When the optical transmission device 10 starts operating, the control unit 13 sends a signal to start power supply to the power supply unit 14. Upon receiving a signal to start supplying power, the power supply unit 14 supplies power to each optical transceiver 11 via a power line connected to each optical transceiver 11 based on an external power supply. Each optical transceiver 11 is connected to the power supply unit 14 in parallel. The current measurement unit 12 provided for each power supply line measures the current flowing through the power supply line, and sends the measurement result to the current value acquisition unit 112 of the control unit 13.

  When the data of the measurement result of the current flowing through each power supply line is received via the current value acquisition unit 112, the control unit 13 causes the power supply control unit 111 to determine whether or not the optical transceiver 11 has an abnormality by measuring the current value. Is compared with a predetermined reference value. The control unit 13 identifies the current measurement unit 12 that has transmitted the measurement result based on the correspondence between the power supply line and the signal line to which the measurement result is transmitted. Since the current measurement unit 12 is provided for each connection unit of the optical transceiver 11, the control unit 13 determines which position the measurement result indicates the current value of the optical transceiver 11 connected to. Can be.

  The predetermined criterion for determining whether or not the optical transceiver 11 is abnormal is set based on an upper limit value and a lower limit value indicating a range of a current value in which the optical transceiver 11 operates normally. When the measurement result is within the range of the predetermined reference, the control unit 13 continues monitoring the measurement result.

  When the measurement result is out of the range of the predetermined reference, the power supply control unit 111 of the control unit 13 sends a signal to the power supply unit 14 to stop supplying power. When receiving the signal for stopping the power supply, the power supply unit 14 stops the power supply.

  In addition, the control unit 13 may output identification information of the current measurement unit 12 in which an abnormality has occurred and a signal indicating that an abnormality has occurred to a monitoring device or the like connected to the optical transmission device 10. As the identification information of the current measuring unit 12, for example, information of an identifier assigned to each current measuring unit 12 is used. The monitoring device or the like that has received the identification information of the current measuring unit 12 in which the abnormality has occurred and the signal indicating that the abnormality has occurred has caused an abnormality based on the relationship between the identification information of the current measuring unit 12 and the optical transceiver 11. The optical transceiver 11 that is present is determined and notified to an operator or the like.

  The optical transmission device 10 of the present embodiment controls the power supply based on the measurement results of the current supplied to the individual optical transceivers 11, but controls the current supplied to the plurality of connected optical transceivers 11. The power supply may be controlled based on the average value. Further, the configuration may be such that the supply and stop of the power supply can be performed for each optical transceiver 11. With such a configuration, the accuracy of controlling the supply of power to the optical transceiver 11 is further improved.

  The optical transmission device 10 of the present embodiment determines the state of the optical transceiver 11 by monitoring the current supplied to the optical transceiver 11 by the current measurement unit 12 in the optical transmission device 10. The power supplied to each optical transceiver 11 is proportional to the power consumption of each optical transceiver 11. Therefore, when the state of the optical transceiver 11 changes and the power consumption changes, the current value of the current supplied to each optical transceiver 11 changes. Therefore, a change in the state of the optical transceiver 11 can be detected by measuring the current value of the current supplied to each optical transceiver 11.

  The optical transmission device 10 of the present embodiment monitors the current supplied to the optical transceiver 11 by the current measuring unit 12 in the optical transmission device 10, so that the optical transmission device 10 does not pass through the communication bus or the like connected to the optical transceiver 11. The state of the transceiver 11 can be monitored. Further, the optical transmission device 10 of the present embodiment can detect a change in the state of the optical transceiver 11 in a short time based on a change in the current value supplied to the optical transceiver 11. Therefore, the optical transmission device 10 of the present embodiment can quickly determine the state of the optical transceiver 11 such as an abnormality and control the power supply unit 14. As a result, the optical transmission device 10 of the present embodiment can detect a change in the state of the optical transceiver 11 without delay.

(Third embodiment)
A third embodiment of the present invention will be described in detail with reference to the drawings. FIG. 4 shows an outline of the configuration of the optical transmission device 20 of the present embodiment. The optical transmission device of the second embodiment stops supplying power to the optical transceiver when an abnormality of the optical transceiver is detected based on a change in the current value. The optical transmission device of the present embodiment is characterized in that in addition to such a configuration, cooling in the device is controlled based on a current value supplied to the optical transceiver.

  The optical transmission device 20 according to the present embodiment includes an optical transceiver 21, a current measuring unit 22, a control unit 23, a power supply unit 24, and a cooling unit 25. N optical transceivers 21 are provided from the optical transceiver 21-1 to the optical transceiver 21-N (N is a positive integer). Each optical transceiver 21 is connected to the optical transmission device 20 via the connector 100. The configuration and functions of the connector 100 of the present embodiment are the same as those of the connector 100 of the second embodiment. Further, N current measurement units 22 are provided from the current measurement unit 22-1 to the current measurement unit 22-N so as to correspond to the optical transceiver 21, respectively.

  The configurations and functions of the optical transceiver 21 and the current measuring unit 22 of the present embodiment are the same as those of the second embodiment having the same names.

  The configuration of the control unit 23 will be described. FIG. 5 shows a configuration of the control unit 23 of the present embodiment. The control unit 23 of the present embodiment includes a power supply control unit 121, a current value acquisition unit 122, and a cooling control unit 123. The configurations and functions of the power supply control unit 121 and the current value acquisition unit 122 of the control unit 23 of the present embodiment are the same as those of the second embodiment with the same names.

  The cooling control unit 123 of the control unit 23 has a function of controlling the cooling unit 25 based on the measurement result of the current value supplied to the optical transceiver 21. The cooling control unit 123 controls the rotation speed of the fan of the cooling unit 25 based on the measurement result of the current value supplied to the optical transceiver 21. The cooling control unit 123 determines the rotation speed of the fan of the cooling unit 25 based on the average value of the current values sent from the current measurement units 22 via the current value acquisition unit 122, and determines the rotation speed of the fan. The control signal shown is sent to the cooling unit 25. The cooling control unit 123 of the control unit 23 stores data indicating the relationship between the average value of the current value and the rotation speed of the fan of the cooling unit 25 in advance. The cooling control unit 123 of the control unit 23 may control the rotation speed of the fan of the cooling unit 25 based on the amount of change in the current value.

  The power control unit 121 of the control unit 23 controls the stop of the power supply of the power supply unit 24 based on the reference of the current value for detecting the abnormality of the operation of the optical transceiver 21 as in the second embodiment. Further, the current value acquisition unit 122 calculates an average value of the current values sent from each current measurement unit 22.

  The cooling unit 25 cools the inside of the optical transmission device 20 based on the control of the cooling control unit 123 of the control unit 23. The cooling unit 25 of the present embodiment is configured by using an air cooling system using a fan. Upon receiving the information on the number of rotations of the fan from the cooling control unit 123, the cooling unit 25 controls the rotation of the fan so that the number of rotations is equal to the received number of rotations.

  The operation of the optical transmission device 20 according to the present embodiment will be described. When the optical transmission device 20 starts operating, the power supply control unit 121 of the control unit 23 sends a signal to the power supply unit 24 to start supplying power. Upon receiving a signal to start supplying power, the power supply unit 24 supplies power to each optical transceiver 21 via a power line connected to each optical transceiver 21 based on an external power supply. Each optical transceiver 21 is connected to the power supply unit 24 in parallel. The current measurement unit 22 provided for each power supply line measures the current flowing through the power supply line, and sends the measurement result to the current value acquisition unit 122 of the control unit 23.

  When receiving the data of the measurement result of the current flowing through each power supply line, the current value acquisition unit 122 calculates the average value of the measurement results sent from each current measurement unit 22. When the average value of the current measurement results is produced, the cooling control unit 123 determines the rotation speed of the fan of the cooling unit 25 from the calculated average value. When the rotation speed of the fan is determined, the cooling control unit 123 sends a signal indicating the rotation speed of the fan to the cooling unit 25. Upon receiving the information on the number of rotations of the fan from the cooling control unit 123, the cooling unit 25 controls the rotation of the fan so that the number of rotations is equal to the received number of rotations. When the fan of the cooling unit 25 rotates, the inside of the optical transmission device 20 is cooled.

  Further, the power control unit 121 of the control unit 23 compares the measurement result of the current value with a predetermined reference value for determining whether or not the optical transceiver 21 is abnormal. When the measurement result is out of the predetermined reference range, the power supply control unit 121 sends a signal to the power supply unit 24 to stop supplying power. When receiving the signal for stopping the power supply, the power supply unit 24 stops the power supply. The optical transmission device 20 according to the present embodiment cools the inside of the device when the power consumption in the optical transceiver 21 increases, and determines that an abnormality has occurred when the power consumption further increases. Supply has been stopped. By performing such control, the optical transmission device 20 of the present embodiment can operate more stably.

  The optical transmission device 20 according to the present embodiment includes only one cooling unit 25, but may include a plurality of cooling units 25. In the case where a plurality of cooling units 25 are provided, the number of cooling units 25 that operate according to the measured current value may be changed. Further, the cooling unit 25 may be provided so as to correspond to each optical transceiver 21. When the cooling unit 25 is provided so as to correspond to the optical transceiver 21, the cooling control unit 123 of the control unit 23 controls the operation of the cooling unit 25 based on the measurement result of the current for each optical transceiver 21. You may.

  In the optical transmission device 20 of the present embodiment, a current supplied to the optical transceiver 21 is measured by a current measurement unit 22 in the optical transmission device 20, and the cooling unit 25 is controlled based on the measurement result. The optical transmission device 20 according to the present embodiment changes the rotation speed of the fan in the cooling unit 25 in a short time in response to the change in the state of the optical transceiver 21 based on the change in the current value supplied to the optical transceiver 21. be able to. Therefore, the optical transmission device 20 of the present embodiment can control the cooling unit 25 without delaying the change in the operation state of the optical transceiver 21.

(Fourth embodiment)
A fourth embodiment of the present invention will be described in detail with reference to the drawings. FIG. 6 shows an outline of the configuration of the optical transmission device 30 of the present embodiment. The optical transmission device according to the third embodiment measures the current value of the current flowing through the power supply line, but the optical transmission device according to the present embodiment measures the current value based on the measurement result of the voltage drop before and after the connector. It is characterized in that it is calculated.

  The optical transmission device 30 according to the present embodiment includes an optical transceiver 31, a voltage measuring unit 32, a control unit 33, a power supply unit 34, and a cooling unit 35. N optical transceivers 31 are provided from the optical transceiver 31-1 to the optical transceiver 31-N (N is a positive integer). Each optical transceiver 31 is connected to the optical transmission device 30 via the connector 101. Further, N voltage measuring units 32 are provided from the voltage measuring unit 32-1 to the voltage measuring unit 32-N so as to correspond to the optical transceiver 31, respectively.

  The configurations and functions of the power supply unit 34 and the cooling unit 35 are the same as those of the second embodiment with the same names.

  The optical transceiver 31 has the same configuration and function as the optical transceiver 11 of the second embodiment. The optical transceiver 31 has the same configuration as that of the second embodiment, and is connected with wiring for measuring a voltage difference before and after a connector 101 for connection with the optical transmission device 30.

  The voltage measuring unit 32 measures a voltage difference before and after the connector 101. The voltage measurement unit 32 sends the measurement result of the voltage difference to the control unit 33. The voltage measuring unit 32 is connected to a power supply line on the optical transmission device 30 side with respect to the connector 100 and a power supply line on the internal side of the optical transceiver 31 with respect to the connector 101.

  The configuration of the control unit 33 will be described. FIG. 7 shows a configuration of the control unit 33 of the present embodiment. The control unit 33 includes a power supply control unit 131, a current value calculation unit 132, and a cooling control unit 133. The configurations and functions of the power control unit 131 and the cooling control unit 133 of the present embodiment are the same as those of the third embodiment having the same names.

  The current value calculation unit 132 calculates the value of the current flowing through the power line based on the measurement result of the voltage difference input from each voltage measurement unit 32. The current value calculation unit 132 calculates a voltage drop value as a voltage difference input from each voltage measurement unit 32, and calculates a current value. The current value calculation unit 132 stores the value of the contact resistance of the connector 101 in advance. The power control unit 131 and the cooling control unit 133 determine the state of each optical transceiver 31 based on the current value calculated by the current value calculation unit 132. The power control unit 131 determines the operation state of the optical transceiver 31 based on the current value calculated by the current value calculation unit 132, and controls the power supply unit. The cooling control unit 133 determines the operation state of the optical transceiver 31 based on the current value calculated by the current value calculation unit 132, and controls the cooling unit 35.

  The connector 101 is provided as a connection unit for connecting the optical transceiver 31. The connector 101 has a signal line for inputting and outputting signals transmitted and received by the optical transceiver 31, a power supply line, a communication bus for inputting and outputting control signals, and the like. Further, the connector 101 has a wiring for measuring a voltage difference of the power supply line before and after passing through the connector 101.

  The operation of the optical transmission device 30 according to the present embodiment will be described. When the optical transmission device 30 starts operating, the power supply control unit 131 of the control unit 33 sends a signal to the power supply unit 34 to start supplying power. Upon receiving a signal to start supplying power, the power supply unit 34 supplies power to each optical transceiver 31 via a power supply line connected to each optical transceiver 31 based on an external power supply.

  When the power supply is started, the voltage measurement unit 32 provided for each power supply line measures the voltage difference between the front and rear of the connector 100 and sends the measurement result to the current value calculation unit 132 of the control unit 33.

  When receiving the measurement result of the voltage difference corresponding to the voltage drop before and after the connector 101 of each power supply line, the current value calculation unit 132 calculates the current value from the voltage difference. After calculating the current value, the current value calculation unit 132 calculates an average value of the current values calculated from the measurement results of the voltage measurement units 32.

  When the average value of the current measurement results is calculated, the cooling control unit 133 determines the rotation speed of the fan of the cooling unit 35 from the average value calculated by the current value calculation unit 132. When the rotation speed of the fan is determined, the cooling control unit 133 sends a signal indicating the rotation speed of the fan to the cooling unit 35. Upon receiving information on the number of rotations of the fan from the cooling control unit 133, the cooling unit 35 controls the rotation of the fan so that the number of rotations is equal to the received number of rotations. When the fan of the cooling unit 35 rotates, the inside of the optical transmission device 30 is cooled.

  In addition, the power supply control unit 131 of the control unit 33 compares the current value calculated by the current value calculation unit 132 with a predetermined reference value for determining whether the optical transceiver 31 has an abnormality. When the calculated current value is out of the predetermined reference range, the power supply control unit 131 sends a signal to the power supply unit 34 to stop supplying power. When receiving the signal for stopping the power supply, the power supply unit 34 stops the power supply.

  The optical transmission device 30 of the present embodiment calculates the current value of the current supplied to the optical transceiver 31 based on the voltage drop before and after the connector, and controls the cooling unit 35 based on the calculated current value. As in the third embodiment, the optical transmission device 30 according to the present embodiment responds to a change in the state of the optical transceiver 31 in a short time based on a change in the current value supplied to the optical transceiver 31 and provides a cooling unit. The fan speed at 35 can be changed. Therefore, the optical transmission device 30 of the present embodiment can control the cooling unit 35 without being delayed by a change in the operation state of the optical transceiver 31.

  In the optical transmission devices of the third and fourth embodiments, the cooling unit is controlled based on the change in the power supplied to the optical transceiver, but the control and monitoring of components other than the cooling unit are performed based on the change in the power. May be performed. In such a configuration, the current value serving as a criterion for control or monitoring is set according to the control target or the target. Further, in the optical transmission device of each embodiment, insertion and removal of the optical transceiver may be detected based on changes in current and voltage supplied to the optical transceiver.

  Although the optical transmission device of each embodiment performs monitoring and control based on the result of comparing the current value with the reference, the reference is set based on the current and voltage fluctuation values, and the current and voltage fluctuations are set. The monitoring and control may be performed based on the measurement result of. By adopting such a configuration, it is possible to cope with a sudden change in the state of the optical transceiver, such as a measured value such as a current value, within the standard, thereby further improving monitoring and control accuracy. Can be.

DESCRIPTION OF SYMBOLS 1 Optical transmission device 2 Connection means 3 Power supply means 4 Acquisition means 5 Monitoring means 10 Optical transmission device 11 Optical transceiver 12 Current measurement unit 13 Control unit 14 Power supply unit 20 Optical transmission device 21 Optical transceiver 22 Current measurement unit 23 Control unit 24 Power supply Unit 25 Cooling unit 30 Optical transmission device 31 Optical transceiver 32 Voltage measuring unit 33 Control unit 34 Power supply unit 35 Cooling unit 100 Connector 101 Connector 111 Power control unit 112 Current value acquisition unit 121 Power supply unit 122 Current value acquisition unit 123 Cooling control unit 131 power control unit 132 current value calculation unit 133 cooling control unit

Claims (10)

Connecting means for connecting the optical transceiver via the connector, having a connector for connecting the optical transceiver,
Power supply means for supplying power to the optical transceiver via the connector,
Acquisition means for acquiring information on the power supplied to the optical transceiver via the connector,
Monitoring means for monitoring the state of the optical transceiver based on the power information.   The optical transmission device according to claim 1, wherein the acquisition unit acquires the power information by measuring a current value output to the optical transceiver via the connector.   The acquisition means measures a voltage difference before and after passing through the connector, calculates a current value based on the voltage difference and a contact resistance of the connector, and acquires the power information. Item 2. The optical transmission device according to item 1. Cooling means for cooling by rotation of a fan;
The optical transmission device according to any one of claims 1 to 3, further comprising: a cooling control unit configured to control rotation of the fan based on the information on the power acquired by the acquisition unit.   When the power supplied to the optical transceiver is equal to or higher than a preset reference, the power control unit stops power supply from the power supply unit when detecting based on the power information. The optical transmission device according to any one of claims 1 to 4, wherein: Multiple optical transceivers,
An optical transmission device according to any one of claims 1 to 5, comprising:
The optical transmission system, wherein the monitoring unit acquires information on the power supplied to each of the plurality of optical transceivers, and monitors a state of each of the optical transceivers based on the information on the power. A connector for connecting an optical transceiver, the optical transceiver is connected via the connector,
Supplying power to the optical transceiver via the connector;
Obtaining information on the power supplied to the optical transceiver via the connector,
Monitoring a state of the optical transceiver based on the power information.   The control method according to claim 7, wherein the power information is obtained by measuring a current value output to the optical transceiver via the connector.   The voltage difference between before and after passing through the connector is measured, and the power information is obtained by calculating the current value based on the voltage difference and the contact resistance of the connector. The control method described. Controlling the rotation of the fan based on the information of the power,
The control method according to claim 7, wherein the inside of the apparatus is cooled by rotation of the fan.

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