JP2012114648A - Optical transmission device, optical transmission system and optical module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical transmission system that can economically realize a redundant configuration in a transmission path.SOLUTION: An optical transmission device branches an electric signal to be transmitted to a transmission path into a first electric signal and a second electric signal; converts the first electric signal and the second electric signal into a first optical signal and a second optical signal of predetermined wavelengths, respectively; transmits the first optical signal to a first transmission path, and the second optical signal to a second transmission path; receives a third optical signal of the predetermined wavelength from the first transmission path, and a fourth optical signal of the predetermined wavelength from the second transmission path, converts the third optical signal and the fourth optical signal into a third electric signal and a fourth electric signal, respectively; and selects either one of the third electric signal and the fourth electric signal.

Description

  The present invention relates to an optical transmission apparatus, and more particularly to an optical transmission apparatus that multiplexes optical signals.

  In recent years, an optical transmission system capable of transmitting a large amount of data at high speed has been widely used. The simplest configuration of such an optical transmission system is shown in FIG.

  FIG. 11 is a block diagram showing a configuration of a conventional single optical transmission system.

  The single optical transmission system shown in FIG. 11 includes a terminal 10 on the local station side, a transmission apparatus 11 on the local station side, a transmission path 12, a transmission apparatus 13 on the opposite side, and a terminal 14 on the opposite side.

  The terminal 10 on the local station side has a function of generating data, transmitting the generated data, and a function of receiving data and processing the received data. The transmission apparatus 11 on the local station side transmits the data transmitted from the terminal 10 on the local station side via the transmission path 12 and transmits the data transmitted on the transmission path 12 to the terminal 10 on the local station side. A transmission device having a function.

  The opposite transmission device 13 has the same function as the transmission device 11 on the local station side. Further, the terminal 14 on the opposite side has the same function as the terminal 10 on the local station side.

  The transmission apparatus 11 on the local station side includes a transponder unit 202 and a monitoring control unit 204. The opposite transmission device 13 includes a transponder unit 212 and a monitoring control unit 214.

  According to the single-mode optical transmission system shown in FIG. 11, data can be transmitted and received between the terminal 10 on the local station side and the terminal 14 on the opposite side. However, when an abnormality occurs in the transmission line 12, the single-mode optical transmission system cannot transmit and receive data between the terminal 10 on the local station side and the terminal 14 on the opposite side.

  In order to avoid such an adverse effect, a duplex configuration is adopted in the optical transmission system, and the active line and the standby line are provided in advance. A duplexed optical transmission system has been proposed in which a line effective for transmission) is switched to a backup line to avoid a communication failure on the line (see, for example, Patent Document 1).

  FIG. 12 is a block diagram showing a configuration of a conventional duplexed optical transmission system.

  Of the constituent elements included in the duplexed optical transmission system of FIG. 12, the same constituent elements as those shown in FIG.

  The duplex optical transmission system shown in FIG. 12 includes a terminal 10 on the local station side, a transmission apparatus 21 on the local station side, transmission paths 12 and 15, a transmission apparatus 23 on the opposite side, and a terminal 14 on the opposite side. . The transmission apparatus 21 on the own station side includes transponder units 202 and 203, a monitoring control unit 204, and a switching unit 201.

  The transponder unit 202 has a function of detecting an abnormality in the transmission path 12. The transponder unit 202 transfers the data transmitted from the switching unit 201 to the transmission path 12 and transmits the data transmitted from the transmission path 12 to the switching unit 201.

  The transponder unit 202 has a function of multiplexing and demultiplexing data to be transmitted to the transmission path 12. Further, it has a function of multiplexing and demultiplexing data transmitted from the transmission path 12. Therefore, the transmission line 12 is implemented by a single optical fiber.

  The transponder unit 203 has the same function as the transponder unit 202, but transmits data to the transmission path 15 and receives data from the transmission path 15. The monitoring control unit 204 periodically collects the line states of the transmission lines 12 and 15 monitored by the transponder units 202 and 203. Then, the switching unit 201 is instructed to switch the transmission path according to the collected line state.

  A general transmission apparatus includes a plurality of transponder units for one monitoring control unit. For this reason, the monitoring process from the monitoring control unit 204 of FIG. 12 to the transponder units 202 and 203 is a periodic collection process, that is, a periodic monitoring process by a program that implements the monitoring control unit 204.

  The opposite transmission device 23 has the same function as the transmission device 21 on the local station side. The transponder units 202 and 203, the monitoring control unit 204, and the switching unit 201 provided in the transmission device 21 on the local station side are the transponder units 212 and 213, and the monitoring control unit 214 provided on the transmission device 23 on the opposite side. This is the same as the switching unit 211.

  The optical transmission system employing the duplex configuration shown in FIG. 12 is provided with two lines, the transmission line 12 and the transmission line 15 in advance, in the transmission apparatus 21 on the local station side and the transmission apparatus 23 on the opposite side. Two lines are switched by the switching units 201 and 211. When a failure occurs in any of the lines, the communication failure is avoided by switching the two lines.

  Next, an overview of the switching operation in the duplexed optical transmission system shown in FIG. 12 will be described. In the following description, it is assumed that the transmission line 12 is an active line and the transmission line 15 is a standby line.

  The data transmitted from the terminal 10 on the local station side is branched into two via the transmission device 21 on the local station side, and is transmitted to the transmission line 12 that is the working line and the transmission line 15 that is the protection line. Is done. Here, the data sent to the transmission line 12 and the transmission line 15 are the same data, and are the data copied in the switching unit 201.

  Then, when a line failure occurs in the transmission path 12, the transponder unit 212 in the transmission apparatus 23 on the opposite side detects that the line is abnormal.

  The monitoring control unit 214 in the opposite transmission apparatus 23 periodically collects the results generated by the line state monitoring by the transponder units 212 and 213. As a result of monitoring, the monitoring control unit 214 has the transponder unit 213 connected to the standby system line (transmission path 15) and the transponder section 212 connected to the active system line (transmission path 12) is in an abnormal line state. Is determined to be in the normal state, the switching unit 211 is instructed to switch the working line from the transmission line 12 to the transmission line 15.

  After receiving the switching instruction from the monitoring control unit 214, the switching unit 211 changes the data to be transmitted to the terminal 14 on the opposite side from the data received from the transponder unit 212 to the data received from the transponder unit 213. change. With these switching processes, the working line is switched from the transmission path 12 to the transmission path 15, so that the optical transmission system can avoid a communication failure.

  The duplex optical transmission system as described above includes two transponder units (transponder units 202 and 203) in the transmission device 201 on the local station side, and two transponder units (transponder unit 212) in the transmission device 23 on the opposite side as well. And 213), the equipment introduction cost increases. That is, two lines of transponder units are required according to the number of transmission lines.

  In the duplex optical transmission system as described above, the monitoring control units 204 and 214 need to collect the results of monitoring by the transponder units 202, 203, 212, and 213, and program processing for monitoring and switching Was necessary. For this reason, the cost for creating a program occurs. Further, when the number of transponder units to be monitored increases, the CPU processing speed required for the monitoring control unit 214 is required to be high, and the cost increases.

  In the above-described duplexed optical transmission system, the monitoring and switching route of the line abnormality state passes through the transponder units 202, 203, 212, and 213, the monitoring control units 204 and 214, and the switching units 201 and 211. It is necessary and diverse. Furthermore, since the program processing in the monitoring control units 204 and 214 is periodic monitoring processing, it takes a lot of processing time from the occurrence of a line abnormality to switching the line, and the line cannot be switched immediately.

  Further, when the environment where the single optical transmission system already exists in FIG. 11 is changed to a duplex optical transmission system in order to improve communication reliability, the transmission apparatus 201 on the local station side includes one transponder unit 203 and It is necessary to add the switching unit 201 and add one transponder unit 213 and switching unit 211 to the transmission device 23 on the opposite side. This increases the cost for introducing the device and increases the work cost for changing the system configuration.

JP 2008-219382 A

  The conventional optical transmission system described above has a problem that when the duplex configuration is adopted in the optical transmission system, the equipment cost and the program creation cost increase, and the line cannot be switched immediately when a line abnormality occurs. In addition, when changing from a single optical transmission system to a dual optical transmission system, there is a problem that the cost for preparing the necessary equipment and the operation cost for the change increase.

  An object of the present invention is to provide a duplex optical transmission system that is inexpensive and highly reliable.

  According to a representative aspect of the present invention, an optical transmission apparatus that transmits an optical signal transmitted from a terminal to a transmission path and transmits an optical signal received from the transmission path to the terminal, the optical transmission apparatus Is connected to the first transmission path and the second transmission path, converts an optical signal transmitted from the terminal into an electrical signal, and converts an electrical signal transmitted to the terminal into an optical signal. A first clock regeneration unit that regenerates the clock of the electrical signal transmitted from the terminal side photoelectric conversion unit, and converts the electrical signal transmitted from the first clock regeneration unit into an optical signal, A transmission path side photoelectric conversion section that converts an optical signal received from the transmission path into an electrical signal, and a second clock recovery section that recovers the clock of the electrical signal transmitted from the transmission path side photoelectric conversion section, The transmission line side photoelectric conversion unit A branching unit for branching an electrical signal whose clock has been recovered by the first clock recovery unit into a first electrical signal and a second electrical signal; and a first electrical signal and a second electrical signal, A first converter for converting the first optical signal and the second optical signal having a wavelength; a first transmitter for transmitting the first optical signal to the first transmission line; and the second A second transmitter for transmitting an optical signal to the second transmission path; a first receiver for receiving a third optical signal of a predetermined wavelength from the first transmission path; and the second transmission. A second receiver for receiving a fourth optical signal of a predetermined wavelength from the path, and converting the third optical signal and the fourth optical signal into a third electrical signal and a fourth electrical signal; In order to cause the second conversion unit and the second clock reproduction unit to regenerate the clock, the third electric signal and the fourth electric signal are reproduced. Comprising a selector for selecting one of the electrical signals of the signal.

  According to one embodiment of the present invention, a duplex optical transmission system can be constructed at low cost.

It is a block diagram which shows the basic composition of the transponder part of the 1st Embodiment of this invention. It is a block diagram which shows the basic composition of the transmission line side optical / electrical conversion part of the 1st Embodiment of this invention. It is a block diagram which shows the basic composition of the switching part of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the optical transmission system of the 1st Embodiment of this invention. It is a block diagram which shows the transponder part of the 1st Embodiment of this invention. It is a block diagram which shows the transmission-line side optical / electrical conversion part of the 1st Embodiment of this invention. It is a block diagram which shows the device controller part of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the duplexed optical transmission system of the 1st Embodiment of this invention. It is a sequence diagram which shows the process which switches the active line of the 1st Embodiment of this invention. It is a flowchart which shows the process which switches the active line of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the single optical transmission system of a prior art. It is a block diagram which shows the structure of the duplex optical transmission system of a prior art.

  Next, embodiments of the present invention will be described in detail with reference to the drawings.

(First embodiment)
Here, a basic configuration of the transponder unit will be described.

  FIG. 1 is a block diagram illustrating a basic configuration of the transponder unit 202 according to the first embodiment of this invention.

  FIG. 1 shows an example of the transponder unit 202 provided in the transmission apparatus 21 on the local station side shown in FIG.

  The transponder unit 202 includes a terminal side optical / electrical conversion unit 301, a transmission line side optical / electrical conversion unit 302, a CDR (Clock and Data Recovery) circuit 303, a CDR circuit 304, and a board controller 305.

  The terminal side optical / electrical converter 301 is connected to the terminal 10 on the local station side. The transmission line side optical / electrical converter 302 is connected to the transmission line 12. The CDR circuit 303 regenerates a clock of data (that is, an electric signal) transmitted from the terminal side optical / electrical conversion unit 301. The CDR circuit 304 regenerates a clock of data (that is, an electric signal) transmitted from the transmission path side optical / electrical conversion unit 302. The board controller 305 controls the transponder unit 202.

  Note that the transponder units 203, 212, and 213 in FIG. 12 have the same functions as the transponder unit 202.

  FIG. 2 is a block diagram illustrating a basic configuration of the transmission line side optical / electrical conversion unit 302 according to the first embodiment of this invention.

  The transmission line side optical / electrical conversion unit 302 includes an electric / optical (wavelength 1) conversion unit 401, an optical (wavelength 2) / electrical conversion unit 402, an optical demultiplexing unit 403, and a device controller unit 404.

  The electrical / optical (wavelength 1) conversion unit 401 converts the electrical signal received from the CDR circuit 303 into an optical signal of wavelength 1. The light (wavelength 2) / electrical converter 402 converts the optical signal of wavelength 2 received from the transmission line 12 side into an electrical signal.

  Here, the wavelength 1 is an arbitrary wavelength of the optical signal, and the wavelength 2 is an arbitrary wavelength different from the wavelength 1.

  The optical demultiplexing unit 403 has a function of multiplexing the optical signal of wavelength 1 received from the electrical / optical (wavelength 1) conversion unit 401 and transmitting the multiplexed optical signal to the transmission path 12 side. Further, after separating the optical signal of wavelength 2 from the optical signal received from the transmission path 12 side, the separated optical signal is transmitted to the optical (wavelength 2) / electrical converter 402. The device controller unit 404 is a function for controlling the transmission line side optical / electrical conversion unit 302.

  The optical demultiplexing unit 403 includes two ports that can pass only unique wavelengths. 2 includes a first port 405 that passes only wavelength 1 and a second port 406 that passes only wavelength 2.

  The light (wavelength 2) / electrical converter 402 measures the light intensity of the optical signal received from the transmission path 12. The device controller unit 404 compares the light intensity measured by the light (wavelength 2) / electric conversion unit 402 with a light intensity threshold specified in advance by an administrator or the like, and the light of the optical signal received from the transmission path 12 When the intensity falls below the light intensity threshold, it is determined that the line is abnormal. Thereafter, the board controller 305 is notified that the line state is abnormal.

  FIG. 3 is a block diagram illustrating a basic configuration of the switching unit 201 according to the first embodiment of this invention.

  FIG. 3 shows an example of the switching unit 201 provided in the transmission apparatus 21 on the local station side shown in FIG.

  The switching unit 201 includes a branching unit 321, a selection unit 322, and a board controller 323 that controls the switching unit 201. The switching unit 201 bifurcates the data received from the terminal 10 on the local station side by the branching unit 321 and transmits the data to each of the transponder units 202 and 203. Then, the selection unit 322 selects one of the data received from the transponder units 202 and 203 as the data transmitted from the working line, and transmits the selected data to the terminal 10 on the local station side.

  Further, the switching unit 201 selects, via the board controller 323, the switching instruction received from the monitoring control unit 204, including switching either one of the data received from the transponder unit 202 or the transponder unit 203 as the working line. Notification to the unit 322. Based on the switching instruction, the selection unit 322 selects an active line.

  FIG. 4 is a block diagram illustrating a configuration of the optical transmission system according to the first embodiment of this invention.

  In the following, the same reference numerals are given to the same components in FIG. 4 as those in FIG. 11, and the description thereof will be omitted.

  The optical transmission system according to the first embodiment includes a terminal 10 on the local station side, a transmission apparatus 31 on the local station side, transmission paths 12 and 15, a transmission apparatus 33 on the opposite side, and a terminal 14 on the opposite side. Prepare.

  The optical transmission system of the first embodiment is a system in which the transponder unit 202 is replaced with the transponder unit 221 and the transponder unit 212 is replaced with the transponder unit 222 in the conventional optical transmission system shown in FIG. In addition, the transmission line 15 is added to the conventional optical transmission system shown in FIG.

  Next, the transponder units 221 and 222 will be described with reference to FIG.

  FIG. 5 is a block diagram illustrating the transponder unit 221 according to the first embodiment of this invention.

  The transponder unit 221 is a device in which the transmission path side optical / electrical conversion unit 302 of the transponder unit 202 shown in FIG. The transponder unit 222 is the same as the transponder unit 221.

  FIG. 6 is a block diagram illustrating the transmission line side optical / electrical conversion unit 311 according to the first embodiment of this invention.

  The transmission line side light / electricity conversion unit 311 of the first embodiment includes an electric / light (wavelength 1) conversion unit 411, a light (wavelength 2) / electricity conversion unit 412, and an electric / light (wavelength 2) conversion unit 414. An optical (wavelength 1) / electrical conversion unit 415, a first optical demultiplexing unit 413, a second optical demultiplexing unit 416, a selection unit 418, a branching unit 417, and a device controller unit 419. Prepare.

  The electrical / optical (wavelength 1) conversion unit 411 converts an electrical signal into an optical signal of wavelength 1. The electrical / optical (wavelength 2) conversion unit 414 converts an electrical signal into an optical signal of wavelength 2. The light (wavelength 1) / electric conversion unit 415 converts an optical signal having a wavelength 1 into an electrical signal. The light (wavelength 2) / electrical converter 412 converts an optical signal of wavelength 2 into an electrical signal.

  As described above, the wavelength 1 is an arbitrary wavelength, and the wavelength 2 is an arbitrary wavelength different from the wavelength 1.

  The first optical demultiplexing unit 413 and the second optical demultiplexing unit 416 are optical demultiplexing units each including a first port and a second port. The first port and the second port provided in the first optical demultiplexing unit 413 and the second optical demultiplexing unit 416 have different wavelengths of optical signals to pass therethrough.

  The first port 420 of the first optical demultiplexing unit 413 is a port for transmitting an optical signal to the transmission path 12 and allows only an optical signal having a wavelength 1 to pass through. The second port 421 of the first optical demultiplexing unit 413 is a port for receiving an optical signal from the transmission line 12, and allows only an optical signal having a wavelength 2 to pass therethrough.

  The first port 422 of the second optical demultiplexing unit 416 is a port for receiving an optical signal from the transmission line 15 and allows only an optical signal of wavelength 1 to pass through. The second port 423 of the second optical demultiplexing unit 416 is a port for transmitting an optical signal to the transmission line 15 and allows only an optical signal having a wavelength 2 to pass therethrough.

  The first port 420 and the first port 422 are both ports that allow the wavelength 1 to pass, but the first port 420 is for transmitting an optical signal, and the first port 422 is for receiving an optical signal. The second port 421 and the second port 423 are both ports that allow the wavelength 2 to pass, but the second port 421 is for receiving an optical signal, and the second port 423 is for transmitting an optical signal.

  That is, in the optical transmission system of the first embodiment, the wavelength transmitted to the transmission path side and the wavelength received from the transmission path side are opposite in the transmission path 12 and the transmission path 15.

  The selection unit 418 selects one of the electrical signals received from the light (wavelength 2) / electrical conversion unit 412 and the light (wavelength 1) / electrical conversion unit 415, and transmits the selected electrical signal to the CDR circuit 304. To do. The branching unit 417 transmits the signal received from the CDR circuit 303 to the electrical / optical (wavelength 1) conversion unit 411 and the electrical / optical (wavelength 2) conversion unit 414.

  The optical transmission system according to the first embodiment includes a transmission path side optical / electrical converter 311, two optical demultiplexing units (413, 416), two sets of optical / electrical converters (412, 415), and electric / electrical converters. An optical conversion unit (411, 414), a branching unit 417, and a selection unit 418 are provided.

  FIG. 7 is a block diagram illustrating the device controller unit 419 according to the first embodiment of this invention.

  In FIG. 7, the process of switching the line will be described.

  The device controller unit 419 includes light intensity threshold value comparison units 430 and 431 and a switching determination unit 432.

  The light (wavelength 1) / electrical converter 415 and the light (wavelength 2) / electrical converter 412 always measure the light intensity of the received optical signal. Then, the light (wavelength 1) / electrical conversion unit 415 and the light (wavelength 2) / electrical conversion unit 412 compare the measurement result with the light intensity threshold value comparison unit 430 and the light intensity threshold value comparison of the device controller unit 419 according to the hardware level signal. Each is notified to the unit 431. The measurement result includes information indicating the light intensity (received light intensity) of the optical signal received from each transmission path.

  The light intensity threshold value comparison units 430 and 431 always compare the light intensity of the received optical signal with the light intensity threshold value specified in advance by an administrator or the like. When it is determined that the light intensity is lower than the light intensity threshold, it is determined that the transmission path in which the light intensity is lower than the light intensity threshold is abnormal. Then, the comparison result is transmitted to the switching determination unit 432.

  The switching determination unit 432 refers to the comparison results received from the light intensity threshold value comparison units 430 and 431. As a result, when one transmission line is normal and the other line is abnormal, the selection unit 418 is instructed to switch by a hardware level signal in order to switch the active line to the normal transmission line. When both the two lines are normal or both are abnormal, the switching determination unit 432 does not send an instruction to the selection unit 418.

  The selection unit 418 switches the active line based on the switching instruction received from the device controller unit 419.

  FIG. 8 is a block diagram showing the configuration of the duplexed optical transmission system according to the first embodiment of this invention.

  The transmission device 33 on the opposite side has the same configuration as the transmission device 31 on the local station side. That is, the terminal side optical / electrical conversion unit 501, CDR (Clock and Data Recovery) circuit 503, CDR circuit 504, board controller 505, and transmission path side optical / electrical conversion unit 511 provided in the transponder unit 222 are transponders. The same as the terminal side optical / electrical conversion unit 301, CDR (Clock and Data Recovery) circuit 303, CDR circuit 304, board controller 305, and transmission path side optical / electrical conversion unit 311 included in the unit 221.

  The electrical / light (wavelength 1) conversion unit 611 included in the transmission line side light / electrical conversion unit 511 is the same as the electrical / light (wavelength 1) conversion unit 411 included in the transmission line side light / electrical conversion unit 311. Further, the electrical / light (wavelength 2) conversion unit 614 is the same as the electrical / light (wavelength 2) conversion unit 414, and the light (wavelength 1) / electrical conversion unit 615 is the light (wavelength 1) / electrical conversion unit. The light (wavelength 2) / electrical conversion unit 612 is the same as the light (wavelength 2) / electrical conversion unit 412.

  The first optical demultiplexing unit 613 is the same as the first optical demultiplexing unit 413, and the second optical demultiplexing unit 616 is the same as the second optical demultiplexing unit 416. The selection unit 618 is the same as the selection unit 418, the branching unit 617 is the same as the branching unit 417, and the device controller unit 619 is the same as the device controller unit 419.

  That is, the transmission path side optical / electrical conversion unit 311 and the transmission path side optical / electrical conversion unit 511 can be mounted by the same device. This is achieved by connecting the first optical demultiplexing unit 413 and the second optical demultiplexing unit 616 and connecting the second optical demultiplexing unit 416 and the first optical demultiplexing unit 613. This is because the roadside optical / electrical conversion unit 311 and the transmission pathside optical / electrical conversion unit 511 are oppositely connected, and the optical demultiplexing unit for transmission and reception can be mounted with the same configuration.

  For this reason, the transmission apparatus 31 on the local station side and the transmission apparatus 33 on the opposite side can be provided with the same transmission path side optical / electrical conversion unit, and the manufacturing cost can be reduced.

  A specific signal transmission / reception process by the transponder unit 221 and the transponder unit 222 will be described below.

  The transmission apparatus 31 on the local station side transmits the data received from the terminal 10 on the local station side to the branching unit 417 via the terminal side optical / electrical conversion unit 301 and the CDR circuit 303. The branching unit 417 transmits the same data to the electrical / optical (wavelength 1) conversion unit 411 and the electrical / optical (wavelength 2) conversion unit 414. The electrical / optical (wavelength 1) conversion unit 411 transmits the wavelength 1 data to the first optical demultiplexing unit 413, and the first port 420 transmits the optical signal of wavelength 1 and transmits the data to the transmission line 12. To do.

  The second demultiplexing unit 616 in the transmission apparatus 33 on the opposite side passes only the optical signal having the wavelength 1 out of the optical signal received from the transmission path 12 through the first port 622. Then, the optical signal that has passed through the first port 622 reaches the selection unit 618 via the light (wavelength 1) / electric conversion unit 615.

  Also, the optical signal of wavelength 2 transmitted from the electrical / optical (wavelength 2) conversion unit 414 passes through the second port 423 of the second optical demultiplexing unit 416, and the transmission path 15, first demultiplexing unit The selection unit 618 is reached via the second port 621 in 613 and the light (wavelength 2) / electrical conversion unit 612.

  Further, the transmission apparatus 33 on the opposite side transmits data received from the terminal 14 on the opposite side to the branching unit 617 via the terminal-side optical / electrical conversion unit 501 and the CDR circuit 503. The branching unit 617 transmits the same data to the electrical / optical (wavelength 1) conversion unit 611 and the electrical / optical (wavelength 2) conversion unit 614. The electrical / optical (wavelength 1) conversion unit 611 transmits the wavelength 1 data to the first optical demultiplexing unit 613, and the first port 620 transmits the optical signal of wavelength 1 and transmits the data to the transmission line 15. To do.

  The second demultiplexing unit 416 in the transmission device 31 on the time station side allows only the optical signal of wavelength 1 among the optical signals received from the transmission path 15 to pass through the first port 422. The optical signal that has passed through the first port 422 reaches the selection unit 418 via the light (wavelength 1) / electric conversion unit 415.

  The optical signal of wavelength 2 transmitted from the electrical / optical (wavelength 2) conversion unit 614 passes through the second port 623 of the first optical demultiplexing unit 616 to transmit the transmission line 12 and the first demultiplexing unit. It reaches the selection unit 618 via the second port 421 and the light (wavelength 2) / electric conversion unit 412 in 413.

  In the following, processing when the active line is switched in the transmission apparatus 31 on the local station side will be described.

  FIG. 9 is a sequence diagram illustrating processing for switching the active line according to the first embodiment of this invention.

  The first optical demultiplexing unit 413 in the transmission apparatus 31 on the local station side allows only the optical signal of wavelength 2 among the optical signals received from the transmission path 12 to pass through the second port 421 (1001). The optical signal that has passed through the second port 421 is converted into an electrical signal by the light (wavelength 2) / electrical converter 412 (1002) and transmitted to the selector 418.

  At this time, the light (wavelength 2) / electrical conversion unit 412 measures the light intensity of the optical signal received from the transmission line 12, and measures the light intensity threshold value comparison unit 431 of the device controller unit 419 according to the hardware level signal. The transmitted light intensity. Specifically, the light intensity of the optical signal is converted into a current value, and the converted current value is transmitted to the intensity threshold comparison unit 431 by the hardware level signal.

  After the current value received from the transmission line 12 is transmitted from the light (wavelength 2) / electrical conversion unit 412, the light intensity threshold value comparison unit 431 compares the received current value with a predetermined threshold value ( 1003). If the current value of the electrical signal is equal to or greater than the threshold value, the optical signal received from the transmission line 12 is received with sufficient strength, and thus it is determined that the transmission line 12 is normal. Then, the light intensity threshold value comparison unit 431 transmits to the device controller unit 419 that the transmission path 12 is normal. When the current value of the electrical signal is lower than the threshold value, the device controller unit 419 is notified that the transmission path 12 is abnormal.

  On the other hand, when the optical signal is received from the transmission line 15, the first port 422 of the second optical demultiplexing unit passes only the optical signal of wavelength 1 among the received optical signals (1004). The optical signal that has passed through the first port 422 is converted into an electric signal by the light (wavelength 1) / electric conversion unit 415 (1005) and transmitted to the selection unit 418.

  At this time, the light (wavelength 1) / electrical conversion unit 415 measures the light intensity of the optical signal received from the transmission line 15 and measures the light intensity threshold comparison unit 431 of the device controller unit 419 using the hardware level signal. The transmitted light intensity. Specifically, the light intensity of the optical signal is converted into a current value, and the converted current value is transmitted to the intensity threshold comparison unit 430 by the hardware level signal.

  After the current value received from the transmission line 15 is transmitted from the light (wavelength 1) / electricity conversion unit 415, the light intensity threshold value comparison unit 430 compares the received current value with a predetermined threshold value ( 1006). If the current value of the electrical signal is equal to or greater than the threshold value, the optical signal received from the transmission line 15 is received with sufficient strength, and therefore it is determined that the transmission line 15 is normal. Then, the light intensity threshold value comparison unit 430 transmits to the device controller unit 419 that the transmission path 15 is normal. When the received current value is lower than the threshold value, the device controller unit 419 is notified that the transmission path 15 is abnormal.

  The device controller unit 419 refers to the notifications sent from the light intensity threshold value comparison unit 431 and the light intensity threshold value comparison unit 430, and determines whether to switch the working line (1007). When switching the working line, information indicating the transmission path that should become the working line and an instruction to switch the working line are transmitted to the selection unit 418. The selection unit 418 instructed to switch the working line switches the working line to the normal transmission line (1008).

  FIG. 10 is a flowchart illustrating a process of switching the active line according to the first embodiment of this invention.

  After the operation information of each transmission path is notified from the light intensity threshold comparison unit 430 and the light intensity threshold comparison unit 431 (1010), the device controller unit 419 refers to the information transmitted from the light intensity threshold comparison unit 431, It is determined whether or not the intensity of the optical signal received by the second port 421 of the first optical demultiplexing unit 413 is greater than or equal to a threshold value, that is, whether or not the transmission path 12 is normal (1011).

  If it is determined that the intensity of the optical signal received by the second port 421 of the first optical demultiplexing unit 413 is greater than or equal to the threshold, the device controller unit proceeds to step 1012. On the other hand, when it is determined that the intensity of the optical signal received by the second port 421 is lower than the threshold, the transmission path 12 is abnormal, and the device controller moves to step 1014.

  In step 1012 and step 1014, the device controller unit 419 refers to the information transmitted from the light intensity threshold value comparison unit 430, and the intensity of the optical signal received by the first port 422 of the second optical demultiplexing unit 416 is determined as follows. It is determined whether or not it is equal to or greater than the threshold value, that is, whether or not the transmission path 15 is normal (1012).

  If it is determined in step 1012 that the intensity of the optical signal received by the first port 422 is greater than or equal to the threshold value, the transmission path 12 and the transmission path 15 are both normal, and the device controller unit selects the selection unit 418. Wait for the next notification without instructing to switch.

  In Step 1012, when it is determined that the intensity of the optical signal received by the first port 422 is lower than the threshold value, the device controller unit is received by the second port 421 of the first optical demultiplexing unit 413. Since the optical signal is normal, the selection unit 418 is instructed to switch the working line to the second port 421 of the first optical demultiplexing unit 413 (1013).

  If it is determined in step 1014 that the intensity of the optical signal received by the first port 422 is greater than or equal to the threshold, the device controller unit is received by the first port 422 of the second optical demultiplexing unit 416. Since the optical signal is normal and the second port 421 of the first optical demultiplexing unit 413 is abnormal, the selection unit 418 is instructed to switch to the first port 422 of the second optical demultiplexing unit 416 ( 1015).

  In step 1014, if it is determined that the intensity of the optical signal received by the first port 422 is lower than the threshold, the device controller unit instructs the selection unit 418 to perform switching because any transmission path is abnormal. Without waiting for the next notification.

  As described above, the processes in the light (wavelength 2) / electric conversion unit 412, the light (wavelength 1) / electric conversion unit 415, the device controller unit 419, and the selection unit 418 are all hardware processes. For this reason, the processing from the abnormality detection in the transmission path to the switching of the transmission path is executed in a short time, and the reliability is improved. In addition, since it is not necessary to use the monitoring control unit 214 to switch the transmission path, the cost for creating a program can be reduced.

  Data received from the transmission line selected as the working line by the selection unit 418 is transmitted to the terminal 11 on the local station side through the CDR circuit 304 and the terminal side optical / electrical conversion unit 301.

  The route for transmitting data from the terminal 14 on the opposite side to the terminal 10 on the own station side is also the same route as described above, and a description thereof will be omitted.

  As described above, the local station side transmission device 31 and the opposite side transmission device 33 according to the present invention each switch a working system line in the transponder unit, so that one transmission device (the local station side transmission device 31 or the opposite side transmission device 31). It is not necessary to arrange two transponder parts in the transmission device 33) on the side. For this reason, the cost for preparing an apparatus can be reduced.

  In addition, transmission line monitoring and line switching in the monitoring control unit 204 and the monitoring control unit 214 are not required. For this reason, the cost for creating a program in the monitoring control unit 204 and the monitoring control unit 214 can be reduced.

  Further, a transponder unit having a different configuration is used for a conventional transponder unit for transmission and a transponder unit for reception. However, as described above, the transmission apparatus of the first embodiment can use the same transponder unit for the transponder unit for transmission and the transponder unit for reception.

  For this reason, the required number of terminal side optical / electrical converters 301 and 501 and CDR circuits 303, 304, 503, and 504 can be reduced by half compared to the conventional optical transmission system having a duplex configuration. . As a result, it is possible to save space, thereby reducing the cost for preparing the necessary equipment and the cost for preparing the location for placing the transmission device on the local station side and the transmission device on the opposite side. It becomes possible.

  Note that the transmission line side optical / electrical conversion unit 311 according to the first embodiment of the present invention uses the first port 420 and the first port 422 for transmission and the second port 421 and the second port 423 for reception. Alternatively, the transmission line side optical / electrical conversion unit 511 may use the first port 620 and the first port 622 for transmission and the second port 621 and the second port 623 for reception.

  In this case, the transmission path side optical / electrical conversion unit 311 of the transmission apparatus 31 on the local station side is different from the transmission path side optical / electrical conversion unit 511 of the transmission apparatus 33 on the opposite side, but the first port 420 and the first The electrical / optical converter connected to the port 422 may be mounted by the same device, and the optical / electrical converter connected to the second port 421 and the second port 423 may be mounted by the same device.

  As a result, one transponder unit is arranged in one transmission device, while elements used in the transmission line side optical / electrical conversion unit 311 are reduced, and the transponder unit can be saved in space.

(Second Embodiment)
The duplexed optical transmission system of the second embodiment is a pluggable type in which the transmission line side optical / electrical conversion unit 311 provided in the transponder unit 221 and the transmission line side optical / electrical conversion unit 511 provided in the transponder unit 222 can be replaced. Mounting by optical module. Accordingly, when the conventional single optical transmission system is changed to a duplex optical transmission system for reasons such as improving communication quality, the transmission line side optical / electrical conversion unit 302 in FIG. A duplexed optical transmission system can be mounted only by exchanging with the transmission line side optical / electrical converter 511.

  As a result, the duplexed optical transmission system of the second embodiment can reduce the cost for preparing equipment and the cost required for the work for changing the configuration of the transmission apparatus.

  Specifically, in the optical transmission system having a single-layer configuration in FIG. 11, the transmission path side optical / electrical conversion unit in the transmission apparatus 11 on the local station side and the transmission apparatus 13 on the opposite side is a pluggable type transmission path side optical module. When configured, the transmission path side optical / electrical conversion unit 311 or the transmission path side optical / electrical conversion unit 511 of this embodiment, which can connect two transmission paths, is replaced. Then, by connecting a new transmission line 15, it is possible to easily construct an optical transmission system having a duplex configuration.

  Thus, it is not necessary to add a new program for line switching to the monitoring control unit 204 and the monitoring control unit 214, and it is not necessary to add a new transponder unit. For this reason, it is possible to reduce the cost for preparing the equipment and to reduce the cost required for the work of changing the configuration of the optical transmission system.

  As described above, according to the present embodiment, when constructing an optical transmission system adopting a duplex configuration proposed for avoiding communication failure on a line, it is not necessary to prepare two transponder units for two lines. That is, since it is only necessary to mount one transponder unit in each transmission apparatus, an optical transmission system having a duplex configuration can be constructed at low cost.

  Further, according to the present embodiment, since the line is switched in the transponder unit, it is not necessary to perform line state monitoring and line switching processing by the monitoring control unit. For this reason, it is possible to reduce the cost for creating a program.

  Further, in the present invention, the measurement of the received optical signal strength and the switching of the line are implemented in the same transmission line side optical / electrical conversion unit, so that the transmission line can be minimized by selecting the optimum transmission line. On the other hand, when a line abnormality is detected, the line can be switched in a short time.

  In addition, when the optical / electrical conversion unit in the optical transmission system having a single configuration already constructed is configured with a replaceable pluggable type optical module, it is easy to replace the pluggable type optical module. It is possible to construct an optical transmission system having a duplex configuration. As a result, when the optical transmission system having a single configuration is changed to an optical transmission system having a dual configuration for reasons such as improving line communication quality, it is possible to reduce the equipment cost and the change work cost.

DESCRIPTION OF SYMBOLS 10 Terminal on the local station 12 Transmission path 14 Terminal 15 on the opposite side Transmission path 31 Transmission apparatus on the local station 33 Transmission apparatus on the opposite side 221 Transponder section 222 Transponder section 301 Terminal side optical / electrical conversion section 303 CDR circuit 304 CDR circuit 311 Transmission path side light / electricity conversion unit 411 Electricity / light (wavelength 1) conversion unit 412 Light (wavelength 2) / electricity conversion unit 413 First optical demultiplexing unit 414 Electricity / light (wavelength 2) conversion unit 415 Light (wavelength 1) Electric conversion unit 416 Second optical demultiplexing unit 417 Branching unit 418 Selection unit 419 Device controller unit 420 First port 421 Second port 422 First port 423 Second port 430 Light intensity threshold comparison unit 431 Light intensity threshold Comparison unit 432 Switching determination unit 501 Terminal side optical / electrical conversion unit 503 CDR circuit 504 CDR circuit 511 Transmission path side optical / electrical Conversion unit 611 Electrical / optical (wavelength 1) conversion unit 612 Optical (wavelength 2) / electrical conversion unit 613 First optical demultiplexing unit 614 Electrical / optical (wavelength 2) conversion unit 615 Optical (wavelength 1) / electrical conversion unit 616 Second optical demultiplexing unit 617 Branching unit 618 Selection unit 619 Device controller unit 620 First port 621 Second port 622 First port 623 Second port

Claims (7)

An optical transmission device that transmits an optical signal transmitted from a terminal to a transmission path, and transmits an optical signal received from the transmission path to the terminal,
The optical transmission device is:
Connected to the first transmission line and the second transmission line;
An optical signal transmitted from the terminal is converted into an electrical signal, and an electrical signal to be transmitted to the terminal is converted into an optical signal.
A first clock recovery unit for recovering a clock of the electrical signal converted by the terminal side photoelectric conversion unit;
A transmission path side photoelectric conversion section that converts an electrical signal transmitted from the terminal side photoelectric conversion section into an optical signal, and converts an optical signal received from the transmission path into an electrical signal;
A second clock recovery unit that recovers the clock of the electrical signal converted by the transmission line side photoelectric conversion unit,
The transmission line side photoelectric conversion unit is:
A branching unit for branching the electrical signal whose clock is recovered by the first clock recovery unit into a first electrical signal and a second electrical signal;
A first converter that converts the first electrical signal and the second electrical signal into a first optical signal and a second optical signal having a predetermined wavelength;
A first transmitter for transmitting the first optical signal to the first transmission path;
A second transmitter for transmitting the second optical signal to the second transmission path;
A first receiver for receiving a third optical signal having a predetermined wavelength from the first transmission line;
A second receiver for receiving a fourth optical signal of a predetermined wavelength from the second transmission path;
A second converter that converts the third optical signal and the fourth optical signal into a third electrical signal and a fourth electrical signal;
And a selection unit that selects one of the third electric signal and the fourth electric signal in order to cause the second clock reproduction unit to regenerate the clock. Transmission equipment. The first conversion unit includes:
A third converter for converting the first electrical signal into the first optical signal having a first wavelength;
A fourth converter that converts the second electrical signal into the second optical signal having a second wavelength;
The first transmission unit transmits the first optical signal converted by the third conversion unit to the first transmission path,
The second transmission unit transmits the second optical signal converted by the fourth conversion unit to the second transmission path,
The first receiving unit receives the third optical signal of the second wavelength from the first transmission path,
The optical transmission apparatus according to claim 1, wherein the second reception unit receives the fourth optical signal having the first wavelength from the second transmission path. The second converter is
A first measuring unit for measuring the intensity of the third optical signal;
A second measuring unit for measuring the intensity of the fourth optical signal,
The transmission line side photoelectric conversion unit compares the measured intensity of the third optical signal with a predetermined threshold, and compares the measured intensity of the fourth optical signal with the predetermined threshold. Part
As a result of the comparison by the comparison unit, when the light intensity of the third optical signal is higher than the threshold value and the light intensity of the fourth optical signal is lower than the threshold value, the selection unit 3. The optical transmission device according to claim 2, wherein three electrical signals are selected. A first optical transmission device and a second optical transmission device comprising the optical transmission device according to claim 2, and the first optical transmission device and the second optical transmission device according to claim 1. An optical transmission system provided opposite to a transmission device,
The first transmission unit of the first optical transmission device transmits the first optical signal having a first wavelength to the second optical transmission device via the first transmission path. Send it to the receiver,
The second transmission unit of the first optical transmission device transmits the second optical signal having a second wavelength to the first optical transmission device via the second transmission path. Send it to the receiver,
The second transmission unit of the second optical transmission device transmits the third optical signal having a second wavelength to the first optical transmission device via the first transmission path. Send it to the receiver,
The first transmission unit of the second optical transmission device transmits the fourth optical signal having a first wavelength to the second optical signal of the first optical transmission device via the second transmission path. An optical transmission system that transmits to a receiving unit. An optical module that transmits an optical signal to a transmission line,
Connected to a first transmission line and a second transmission line for transmitting the optical signal;
A branching section for branching a signal to be transmitted to the first transmission path and the second transmission path into a first electrical signal and a second electrical signal;
A first converter that converts the first electrical signal and the second electrical signal into a first optical signal and a second optical signal having a predetermined wavelength;
A first transmitter for transmitting the first optical signal to the first transmission path;
A second transmitter for transmitting the second optical signal to the second transmission path;
A first receiver for receiving a third optical signal having a predetermined wavelength from the first transmission line;
A second receiver for receiving a fourth optical signal of a predetermined wavelength from the second transmission path;
A second converter that converts the third optical signal and the fourth optical signal into a third electrical signal and a fourth electrical signal;
An optical module comprising: a selection unit that selects one of the third electric signal and the fourth electric signal. The first conversion unit includes:
A third converter for converting the first electrical signal into the first optical signal having a first wavelength;
A fourth converter that converts the second electrical signal into the second optical signal having a second wavelength;
The first transmission unit transmits the first optical signal converted by the third conversion unit to the first transmission path,
The second transmission unit transmits the second optical signal converted by the fourth conversion unit to the second transmission path,
The first receiving unit receives the third optical signal of the second wavelength from the first transmission path,
The optical module according to claim 5, wherein the second receiving unit receives the fourth optical signal having the first wavelength from the second transmission path. The second converter is
A first measuring unit for measuring the intensity of the third optical signal;
A second measuring unit for measuring the intensity of the fourth optical signal,
The electro-optic conversion unit compares a measured intensity of the third optical signal with a predetermined threshold, and compares the measured intensity of the fourth optical signal with the predetermined threshold. Prepared,
As a result of comparison by the comparison unit, when the light intensity of the third signal is higher than the threshold value and the light intensity of the fourth signal is lower than the threshold value, the selection unit The optical module according to claim 6, wherein an electrical signal is selected.

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