JP3588657B2 - Optical line monitoring system - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical line monitoring system that monitors the state of an optical line in a transmission system that performs optical communication such as a telephone communication system.
[0002]
[Prior art]
The transmission system 100 in which the main device 110 and the slave device 120 (120a, 120b,..., 120m) are connected by the optical multiplexer / demultiplexer 130, the common optical line 140, and the slave device-side optical line 150 (150a, 150b,. A conventional example of the configuration of the optical line monitoring system in the (point-multipoint optical communication system 100) will be described with reference to FIG. An optical line monitoring device 190 including a test machine 191, a test control device 192, a fiber core selection device 193, and an optical branching module 194 (194a, 194b,. Each of the slave device-side optical paths 150 is interposed between them and monitors each of them. At this time, a large optical loss occurs due to the power splitting in the optical splitting module 194, which undesirably affects the received light power level in the master device 110 and / or the slave device 120.
Also, in order to keep the received light power level high in the main unit 110 and the subordinate units 120 (120a, 120b,..., 120m) and to enable transmission at a high bit rate, as shown in FIG. 16), a transmission system 100 ′ is known that uses a wavelength router 170 with a small optical loss and performs communication using an optical signal having a wavelength that matches the routing characteristics of the wavelength router 170. The transmission system 100 'uses an optical line monitoring system that inserts an optical line monitoring device 190' into the slave device-side optical line 150 and monitors each of the slave device-side optical lines 150.
[0003]
[Problems to be solved by the invention]
However, since the optical line monitoring device 190 'is inserted in the middle of the slave device side optical line 150 for optical line monitoring, there is a disadvantage that a large optical loss occurs due to power branching. Also, in the case of the optical line monitoring device 190 ', it is necessary to connect each one of the slave device-side optical lines 150 to the optical line monitoring device 190', which is inconvenient to install and handle. There were also disadvantages.
As described above, in the conventional optical line monitoring systems 100 and 100 ', there is a problem that a large optical loss due to the optical line monitoring devices 190 and 190' occurs constantly and a problem that installation and handling are inconvenient. . In addition, there is a problem that monitoring of the optical line 140 connecting the main device 110 and the optical multiplexer / demultiplexer 130 (FIG. 16) and monitoring of each optical line 150 connecting the main device 110 and the wavelength router 170 (FIG. 17) cannot be performed. .
Therefore, an object of the present invention is to provide an optical line monitoring system capable of minimizing optical loss as much as possible, easily installing and handling, and improving the reliability of a transmission system.
[0004]
[Means for Solving the Problems]
In order to solve the above problems, the present inventors have conducted intensive studies and completed the present invention. That is, the present invention provides an optical line for monitoring an optical line in a transmission system in which an optical communication is performed by connecting a main device and a plurality of subordinate devices via an optical line via a multiple-input multiple-output passive wavelength router. It is a monitoring system.
This optical line monitoring system(1)A tester that transmits and receives monitoring optical signals of a plurality of wavelengths for monitoring a slave device side optical line that connects a slave device and the wavelength router among the optical lines, and a test controller that controls the test machine. An optical line monitoring device comprising: in addition,(2)Each of the slave devices of the transmission system includes a reflection unit that reflects the monitoring optical signal. further,(3)An input port on the side where the main unit of the tester and the wavelength router is connectedAny input port different from the input port connected to the main unitAre connected by a monitoring optical line. And the testing machine is(1)Transmitting the monitoring optical signal to the slave device via the wavelength router,(2)The monitoring optical signal reflected by the reflection means provided in the slave device is received again via the wavelength router, whereby the slave device-side optical line is monitored. 1).
[0005]
According to this configuration, the monitoring optical signal of the predetermined wavelength transmitted from the tester passes through the specific slave device-side optical line according to the wavelength of the monitoring optical signal and passes through the specific characteristic according to the routing characteristic of the wavelength router. Reach the slave device. Then, the light is reflected by the slave device, passes through a specific slave device-side optical line, and is returned to the tester by the routing characteristics of the wavelength router. Thus, it is possible to monitor an abnormality such as the presence / absence of disconnection of the optical line on the slave device side without causing optical loss due to power branching.Further, installation and handling of the system is easy.The tester can transmit and receive monitoring optical signals of different wavelengths at least as many as the number of slave devices.
[0006]
Further, in the optical line monitoring system of the present invention, the wavelength router includes a main device side optical line that connects the main device and the wavelength router to an output port on a side to which the plurality of slave devices are connected. It has a monitoring output port for monitoring, and monitors the main device side optical line by transmitting an optical signal transmitted from the main device as a monitoring optical signal to the monitoring output port. (Claim 2).
[0007]
According to this configuration, the main device transmits the monitoring optical signal. This monitoring optical signal passes through the main device side optical line and reaches an output port to which the slave device of the wavelength router is not connected, without power splitting. Based on the arrived monitoring optical signal, it is possible to monitor an abnormality such as the presence or absence of disconnection of the main device side optical line. In the monitoring optical signal transmitted by the main device, the wavelength reaching the output port (monitoring output port) to which the slave device of the wavelength router is not connected is set according to the routing characteristics of the wavelength router.
[0008]
Further, in the optical line monitoring system of the present invention, the monitoring optical signal transmitted from the main device to the monitoring output port is provided by the following means.(1)Or means(2)The input to the main device or the testing machine may be performed by any of the means to monitor the optical line on the main device side (claim 3).
(means1The monitoring output port includes a reflection unit, and reflects the monitoring optical signal transmitted from the main device at the reflection unit, and inputs the monitoring optical signal to the main device via the wavelength router and the main device side optical line. .
(means2The monitoring output port is connected to the tester via an optical line, and a monitoring optical signal transmitted from the main device is input to the tester via the optical line.
[0009]
means(1)According to the method, the monitoring optical signal that has reached the monitoring output port is reflected by the reflection unit, and is returned to the main device without power splitting according to the routing characteristics of the wavelength router. Whether or not the main device side optical line is disconnected can be determined by the main device or the optical line monitoring device.
means(2)According to this, the monitoring optical signal that has reached the monitoring output port is input to the tester via a dedicated optical line. Whether or not the main device side optical line is broken can be determined by the optical line monitoring device.
[0010]
Further, in the optical line monitoring system of the present invention, the reflecting means provided in the slave device includes the following.Reflecting means(Claim 4).
The slave device has a filter for multiplexing / demultiplexing optical signals in a plurality of wavelength bands, and this filter allows a monitoring optical signal transmitted from the optical line monitoring device and a communication optical signal transmitted from the main device. Are reflected (branched), and the monitoring optical signal transmitted from the optical line monitoring device is reflected by the reflection unit among the separated optical signals, and the reflected monitoring optical signal is returned to the original through the filter. Reflecting means for guiding to an optical line and multiplexing with a communication optical signal transmitted and received by the main device.
[0011]
SaidAccording to the reflection means,Only the monitoring optical signal is reflected. Therefore, it is possible to monitor the optical line on the slave device side while performing the optical communication.
[0012]
Further, in the optical line monitoring system of the present invention, when there are a plurality of the transmission systems to be monitored, the input ports of the respective wavelength routers of the plurality of transmission systems and the tester are connected via an optical switch. By connecting the monitoring optical lines and switching the optical switches, monitoring of the optical lines in any of the plurality of transmission systems can be performed..
[0013]
According to this configuration, even if there are a plurality of transmission systems to be monitored, monitoring can be performed by one optical line monitoring device.
[0014]
In the optical line monitoring system of the present invention, the main device and the tester are connected by an optical line, and an optical signal transmitted / received by the main device and a monitoring light transmitted / received by the tester are provided to the main device. A multiplexing / demultiplexing unit for multiplexing / demultiplexing a signal may be provided, and the main device side optical line may also serve as the monitoring optical line. The tester transmits and receives a monitoring optical signal for monitoring the optical path on the slave device side via the optical line on the main device side.5).
[0015]
According to this configuration, the monitoring of the optical line on the slave device side and the monitoring of the optical line on the main device side can be performed simultaneously.
The monitoring optical signal for monitoring the optical line on the main device side is transmitted by the main device or the tester. When the monitoring optical signal is transmitted by the main apparatus, an unused communication optical signal can be used as a monitoring optical signal for monitoring the optical path on the main apparatus side. When the monitoring optical signal is transmitted by the tester, an unused monitoring optical signal for monitoring the optical line on the slave device is used as a monitoring optical signal for monitoring the optical line on the main device side. be able to.
It should be noted that n and N in the present specification mean a number of 2 or more, and do not necessarily mean the 14th alphabet. Similarly, m means a number of 2 or more smaller than n.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
First, a transmission system to which the optical line monitoring system according to the present embodiment is applied will be described.
[0017]
≪Transmission system≫
As shown in FIG. 1, the transmission system 1 includes a main device 10, a subordinate device 20 (20a, 20b,..., 20m), a wavelength router 70, a main device side optical line 40 connecting the main device 10 and the wavelength router 70, It comprises a slave device side optical line 50 (50a, 50b,... 50m) connecting the router 70 and the slave device 20. The transmission system 1 performs point-multipoint optical communication.
[0018]
The main device 10 can transmit a communication optical signal λ of a plurality of wavelengths to the slave device 20. In addition, the main device 10 can receive communication optical signals λ of a plurality of wavelengths from the subordinate device 20.
[0019]
The slave device 20 receives the (one) communication optical signal λ of the specific wavelength among the communication optical signals λ of the plurality of wavelengths transmitted by the main device 10, and the specific wavelength received toward the main device 10. The communication optical signal λ having the same wavelength as the communication optical signal λ can be transmitted.
[0020]
As described above, there are two optical lines composed of optical fibers and the like, the main unit side optical line 40 and the slave unit side optical line 50 (50a, 50b,..., 50m). The slave device-side optical line 50 is an individual optical line that individually connects the wavelength router 70 and the slave device 20 (20a, 20b,..., 20m). The main device side optical line 40 transmits (guides) a communication optical signal λ on which a plurality of wavelengths are superimposed.
[0021]
The wavelength router 70 used in this embodiment is an n-port input n-port output wavelength router. In the present embodiment, of the wavelength router 70, the port to which the main device 10 is connected is called an input port unit 70P, and the port to which the subordinate device 20 is connected is called an output port unit 70Q.
The input port unit 70P has a plurality of input ports. The main device 10 is connected to one input port of the plurality of input ports via the main device side optical line 40. The output port unit 70Q also has a plurality of output ports, and each of the slave devices 20 (20a, 20b,..., 20m) is controlled by a separate slave device-side optical line 50 (50a, 50b,. It is connected.
[0022]
Here, the operation principle of the wavelength router 70 will be described with reference to FIG. FIG. 2 is a diagram illustrating functions of the wavelength router.
The input port unit 70P of the wavelength router 70 has n input ports of 70Pa to 70Pn. The output port unit 70Q also has n output ports 70Qa to 70Qn.
[0023]
The wavelength router 70 has a periodic wavelength demultiplexing characteristic (routing characteristic) for each of the input ports 70Pa, 70Pb,... 70Pn, and an optical signal of a specific wavelength input to a specific input port is output to a specific output port. Is passively output (routed) to
Specifically, for example, (1) when an optical signal having a wavelength λk is input to the input port 70Pi-1, the signal is routed to the output port 70Qn-2 of the n output ports 70Q.
Similarly, (2) when an optical signal having a wavelength λk is input to the input port 70Pi adjacent to the input port 70Pi-1 and routed to the output port 70Qn-1 adjacent to the output port 70Qn-2. Is done.
(3) When an optical signal having the wavelength λj is input to the input port 70Pi-1, the output port 70Qn-2 to which the wavelength λk is routed is routed to the output port 70Qn-1 adjacent to the output port 70Qn-1.
In this case, the input / output wavelength difference dλ between adjacent ports is dλ = λj−λk.
[0024]
On the other hand, the output port of the wavelength router 70 also has a periodic wavelength demultiplexing characteristic (routing characteristic) for each of the output ports 70Qa, 70Qb,... 70Qn, and the optical signal of the specific wavelength input to the specific output port is , Passively routed to a particular input port.
Specifically, for example, (1) when an optical signal having a wavelength λk is input to the output port 70Qn-2, it is routed to the input port 70Pi-1 of the n input ports 70P.
Similarly, (2) when an optical signal having the wavelength λk is input to the output port 70Qn-1 adjacent to the output port 70Qn-2, the routing is performed to the input port 70Pi adjacent to the input port 70Pi-1. Is done.
(3) When an optical signal of the wavelength λj is input to the output port 70Qn-1, the input port 70Pi to which the wavelength λk is routed is routed to the next input port 70Pi-1.
Also in this case, the input / output wavelength difference dλ between adjacent ports is dλ = λj−λk.
[0025]
That is, (1) the optical signal of the wavelength λk input to the input port 70Pi-1 is always routed to the output port 70Qn-2. Conversely, the optical signal of the wavelength λk input to the output port 70Qn-2 is always routed to the input port 70Pi-1.
Similarly, (2) the optical signal of the wavelength λk input to the input port 70Pi is always routed to the output port 70Qn-1. Conversely, the optical signal of the wavelength λk input to the output port 70Qn-1 is always routed to the input port 70Pi.
(3) The optical signal of the wavelength λj input to the input port 70Pi-1 is always routed to the output port 70Qn-1. Conversely, the optical signal of the wavelength λj input to the output port 70Qn-1 is always routed to the input port 70Pi-1.
As described above, for the optical signal input to the wavelength router 70, if the position and the wavelength of the input port (output port) are determined, the output port (input port) to be automatically routed is determined.
[0026]
In the transmission system 1 to which the optical line monitoring system A of the present embodiment is applied, the wavelength router 70 can perform optical communication between the master device 10 and the slave device 20 without crosstalk. That is, the main device 10 can communicate with any subordinate device 20 by selecting the wavelength of the communication optical signal λ. On the other hand, the slave device 20 can communicate with the main device 10 by transmitting the communication optical signal λ having the same wavelength as the received communication optical signal λ.
[0027]
Next, an optical line monitoring system according to the present embodiment for monitoring the presence or absence of disconnection of the optical line in the above-described transmission system will be described according to the following first to fourth embodiments.
The optical line monitoring systems according to the first and second embodiments transmit a monitoring optical signal from an optical line monitoring device to a wavelength router using a unique optical line (monitoring optical line). Things. In the optical line monitoring systems according to the third and fourth embodiments, the main device side optical line also serves as a monitoring optical line. In any of the embodiments, the main device side optical line and the slave device side optical line can be monitored.
[0028]
<< 1st Embodiment >>
The optical line monitoring system according to the first embodiment will be described with reference to FIG.
Since the transmission system of the first embodiment has the same configuration and function as the transmission system 1 described above, the same reference numerals are given to the same elements and members in the transmission system, and description thereof will be omitted. I do.
[0029]
[Configuration of optical line monitoring system]
The optical line monitoring system A1 of the first embodiment includes an optical line monitoring device 90, a monitoring optical line 41 connecting the optical line monitoring device 90 and the input port unit 70P of the wavelength router 70, and an output port unit 70Q of the wavelength router 70. The optical line 51 connects the optical line monitoring device 90 and the optical line monitoring device 90, and includes a reflection unit provided in the slave device 20 (see FIG. 1).
[0030]
(1) The configuration of an optical line monitoring system that monitors an optical line on a slave device side will be described.
The optical line monitoring device 90 includes a multi-wavelength compatible test machine 91 (hereinafter referred to as “test machine 91”) and a test control device 92 that controls the test machine 91.
The tester 91 can transmit the monitoring optical signal λ ′ of a plurality of wavelengths to the specific slave device 20 via the wavelength router 70 for each wavelength of the monitoring optical signal λ ′ (this point). Will be described later). Further, the tester 91 can receive the monitoring optical signal λ ′ reflected by the reflection unit provided in the slave device 20 via the wavelength router 70. The monitoring optical signal λ ′ transmitted and received by the tester 91 has a different frequency band from the communication optical signal λ transmitted and received by the main device 10 so as not to hinder communication in the transmission system 1.
Incidentally, the tester 91 (the optical line monitoring device 90) transmits the monitoring optical signal λ ′ of the specific wavelength to the specific slave device 20 and reflects the monitoring optical signal λ of the specific wavelength reflected by the specific slave device 20. By receiving (detecting) ', the presence or absence of disconnection of the optical line is monitored.
Further, the test control device 92 controls the optical line monitoring system A comprehensively, transmits the monitoring optical signal λ ′, and determines whether or not the slave device side optical line 50 has an abnormality.
[0031]
The slave devices 20 each comprise a reflecting means. The reflecting means has a role of reflecting the monitoring optical signal λ ′ transmitted from the tester 91 and returning the signal to the tester 91. On the other hand, the reflection means allows the communication optical signal λ transmitted from the main device 10 to pass. Accordingly, the communication optical signal λ reaches the transmission / reception unit 21 (see FIG. 3) provided in the slave device 20 without being reflected by the reflection unit. In addition, the reflection unit allows the transmission of the communication optical signal λ transmitted from the transmission / reception unit 21 to the main device 10. This allows monitoring of the slave device-side optical line 50 without obstructing communication between the main device 10 and the slave device 20.
[0032]
An example of a specific configuration of the reflection unit will be described with reference to FIGS.
As one example of the reflection means, there is one having a configuration shown in FIG. In this case, the reflection unit is configured to include the filter F1 and the reflection unit R1. This filter F1 has the characteristics shown in FIG.
That is, when the optical signal for communication λ and the optical signal for monitoring λ ′ are superimposed and input to the filter F1 (see FIG. 4A), the filter F1 changes the optical signal for communication λ and the optical signal for monitoring according to the wavelength. The optical signal λ ′ is separated. Then, the communication optical signal λ is guided to the transmission / reception unit 21 on the subsequent stage. As a result, the communication optical signal λ is input to the transmission / reception unit 21. On the other hand, the filter F1 guides the monitoring optical signal λ ′ to the reflection unit R1 on the subsequent stage. The monitoring optical signal λ ′ guided to the reflection unit R1 is reflected here, returns to the filter F1 again, and is sent out to the slave device side optical line 50. Further, the communication optical signal λ transmitted by the transmission / reception unit 21 is also sent out to the slave device side optical line 50 through the filter F1.
Here, as shown in FIG. 4 (b), the filter F1 includes a frequency band of the communication optical signal λ (λa · λb ·· λn) and a monitoring optical signal λ '(λ'a · λ'b ···). λ′n) can be separated.
The reflector R1 is not limited to a specific one as long as it can reflect the monitoring optical signal λ ′, and may be, for example, a vertically cut optical fiber.
[0033]
Further, as another example of the reflecting means, there is one having a configuration shown in FIG. In this case, the filter F2 is the main component of the reflection means. This filter F2 has the characteristics shown in FIG.
That is, when the communication optical signal λ and the monitoring optical signal λ ′ are superimposed and input to the filter F2 (see FIG. 5A), the filter F2 transmits the communication optical signal λ according to the wavelength. And reflects the monitoring optical signal λ ′ (Fresnel reflection). The transmitted communication optical signal λ is input to the transmission / reception unit 21 on the subsequent stage. The monitoring optical signal λ ′ reflected by the filter F2 is returned to the slave device-side optical line 50. The communication optical signal λ transmitted by the transmission / reception unit 21 is transmitted through the filter F2 without being reflected by the filter F2, and is transmitted to the slave device-side optical line 50.
Here, as shown in FIG. 5 (b), the filter F2 includes a frequency band of the communication optical signal λ (λa, λb... Λn) and a monitoring optical signal λ ′ (λ′a λ′b. λ′n) is transmitted through one frequency band and reflects the other frequency band according to the wavelength (the reflected side is the frequency band of the monitoring optical signal λ ′).
[0034]
The monitoring optical line 41 connects the tester 91 of the optical line monitoring device 90 and the wavelength router 70. The monitoring optical line 41 is connected to an arbitrary input port of the input port unit 70P (see FIG. 2) of the wavelength router 70 which is different from the input port to which the main device 10 is connected.
Here, the wavelength router 70 also has the same wavelength demultiplexing characteristic (routing characteristic) as that for the communication optical signal λ for the monitoring optical signal λ ′. Accordingly, the monitoring optical signal λ ′ transmitted from the tester 91 is routed to a specific output port of the wavelength router 70 according to the wavelength, and reaches a specific slave device 20. Further, the monitoring optical signal λ ′ that has reached the specific slave device 20 is reflected by the reflection unit, returns to the wavelength router 70 again, is routed according to the wavelength, and is received by the tester 91 that is the transmission source.
[0035]
Here, a characteristic image of the wavelength router 70 will be described with reference to FIG.
The wavelength router 70 determines the wavelength demultiplexing characteristics in the frequency band of the communication optical signal λ (λa, λb,... Λn) by using the monitoring optical signal λ ′ (λ′a, λ′b,. ).
Here, (1) the communication optical signal λ1 and the monitoring optical signal λ′a are routed to the output port to which the slave device 20a is connected, and (2) the communication optical signal λb and the monitoring optical signal λ ′. b is routed to the output port to which the slave device 20b is connected, and (3) the communication optical signal λm and the monitoring optical signal λ'm are routed to the output port to which the slave device 20m is connected. I do. In this case, (1) #FSR (Free Spectrum Range) of the communication optical signal λa and the monitoring optical signal λ′a, (2) #FSR of the communication optical signal λb and the monitoring optical signal λ′b, (3) The #FSRs of the communication optical signal λm and the monitoring optical signal λ′m all have the same value. That is, if the value of #FSR is the same even if the wavelength band is different, the routing characteristics in the wavelength router 70 are the same.
Therefore, the monitoring optical signal λ ′ transmitted from the tester 91 also reaches the specific slave device 20 according to the wavelength, similarly to the communication optical signal λ transmitted from the main device 10. Further, the monitoring optical signal λ ′ reflected by the reflection unit of the slave device 20 is received by the tester 91 that is the transmission source. In other words, the communication optical signal λ and the monitoring optical signal λ 'having the same #Suffix (subscript) are routed to the same output port (input port).
The characteristics of the wavelength router 70 have periodicity, and the same routing characteristics (wavelength demultiplexing characteristics) are obtained for each integral multiple of the value of #FSR.
[0036]
(2) The configuration of the optical line monitoring system that monitors the optical line on the main device side will be described.
The main device 10 can transmit a monitoring optical signal λ ″ for monitoring the main device side optical line 40 in addition to the communication optical signals λ of a plurality of wavelengths.
[0037]
The output port unit 70Q of the wavelength router 70 has a monitoring output port 70Qz that outputs a monitoring optical signal λ ″. Then, the optical line 51 connects the monitoring output port 70Qz to the test device 91, receives the monitoring optical signal λ ″ transmitted by the main device 10 by the test device 91, and Monitors for disconnections.
[0038]
The wavelength of the monitoring optical signal λ ″ is a frequency in a wavelength band that does not hinder communication between the main device 10 and the slave device 20 and is output to the monitoring output port 70Qz due to the routing characteristics of the wavelength router 70 (routing). ) Is used. An optical signal of an unused wavelength (empty wavelength) of the communication optical signal λ can be assigned to the monitoring optical signal λ ″.
[0039]
[Operation of optical line monitoring system]
The operation of the optical line monitoring system A1 according to the first embodiment will be described with reference to FIG.
[0040]
(1) monitoring the optical line on the slave device side;
For example, when monitoring the first slave device-side optical line 50a, the tester 91 transmits the monitoring optical signal? 'A having a frequency according to the routing characteristics of the wavelength router. The monitoring optical signal? 'A is routed by the wavelength router 70, and reaches the slave device 20a through the slave device side optical line 50a. The monitoring optical signal λ'a that has reached the slave device 20a is reflected by the reflection means, and is received by the tester 91 along the original path.
When the monitoring optical signal λ'a is received by the tester 91, it is determined that there is no abnormality such as disconnection in the slave device-side optical line 50a. If not received by the tester 91, it is determined that there is an abnormality such as a disconnection in the optical path 50a on the slave device side. Also, the presence or absence of an abnormality in the optical line is monitored from the power level of the received monitoring optical signal λ ′. In addition, since light is reflected at the place where the abnormality has occurred, it is possible to monitor where the abnormality has occurred from the length of time that the transmitted monitoring optical signal λ 'is reflected and returned. Here, the selection of the wavelength of the monitoring optical signal λ ′ transmitted by the tester 91 and the determination of the presence or absence of an abnormality in the optical line are performed by the test control device 92.
By the way, when monitoring the second slave device-side optical line 50b, the m-th slave device-side optical line 50m, and the like, the monitoring optical signals λ'b and λ 'having a frequency according to the routing characteristics of the wavelength router, respectively. When the tester 91 transmits m and receives it again, the presence or absence of an abnormality can be monitored.
[0041]
(2) monitoring of the optical line on the main device side;
When monitoring the main device side optical line 40, the main device 10 transmits a monitoring optical signal λ ″ based on a command from the test control device 92. This monitoring optical signal λ ″ reaches the wavelength router 70 through the main device side optical line 40. Then, the signal is routed (output) to the monitoring output port 70Qz according to the routing characteristics of the wavelength router 70, and is received by the tester 91 through the optical line 51. When the monitoring optical signal λ ″ is received by the tester 91, it is determined that the main device side optical line 40 has no abnormality such as disconnection. If the signal is not received by the tester 91, it is determined that there is an abnormality such as a disconnection in the main device-side optical line 40. Also, the presence or absence of an abnormality in the optical line is monitored based on the power level of the received monitoring optical signal λ ″ and the length of the return time.
Here, the test control device 92 adjusts the timing at which the main device 10 transmits the monitoring optical signal λ ″, and determines whether or not the optical line is abnormal.
[0042]
As described above, according to the optical line monitoring system A1 of the first embodiment, since the optical signal for communication and the optical signal for monitoring are multiplexed / demultiplexed by the wavelength router, optical loss due to power branching occurs. It is possible to monitor the optical line for abnormalities. Further, since the frequency band of the optical signal for monitoring is different from the frequency band of the optical signal for communication, communication in the transmission system is not hindered.
[0043]
The above-described monitoring optical signal λ ″ for monitoring the main device side optical line 40 is input to the tester 91 via the optical line 51 connected to the monitoring output port 70Qz of the wavelength router 70. It is. Instead of this configuration, as shown in FIG. 7, the monitoring output port 70Qz of the wavelength router 70 includes a reflection unit R2, and reflects the monitoring optical signal λ ″ output to the monitoring output port 70Qz. Is also good.
In the case of this configuration, the reflected monitoring optical signal λ ″ is again received by the main device 10 through the main device side optical line 40 due to the routing characteristics of the wavelength router 70. The main device 10 converts the signal intensity of the received monitoring optical signal λ ″ into an electric signal and transmits it to the test control device 92, and the test control device 92 determines whether or not the main device-side optical line 40 is disconnected. I do.
In this way, the main unit side optical line can be monitored also by providing the reflection unit at the monitoring output port.
[0044]
<< 2nd Embodiment >>
An optical line monitoring system according to the second embodiment will be described with reference to FIG.
In the second embodiment, a plurality of transmission systems are monitored by one optical line monitoring system A2.
[0045]
[Configuration of optical line monitoring system]
The optical line monitoring system A2 of the second embodiment monitors the slave device side optical line 50 and the main device side optical line 40, similarly to the optical line monitoring system A1 of the first embodiment. However, there are N transmission systems 1 from system A to system N.
Since each transmission system 1 (1A, 1B,... 1N) has the same configuration and function as the transmission system 1 of the first embodiment, the same reference numerals are given to the same elements and members, and Description is omitted.
Similarly, for the optical line monitoring system A2, the same elements and members as those of the optical line monitoring system A1 of the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
[0046]
(1) The configuration of an optical line monitoring system that monitors an optical line on a slave device side will be described.
The optical line monitoring device 90 has an optical switch 93 in addition to the test device 91 and the test control device 92. The optical switch 93 is connected to N wavelength routers 70, 70,... From the system A to the system N by N individual monitoring optical lines 41, 41,. The optical switch 93 is an optical path switch that switches an optical path based on a command from the test control device 92. With this optical switch 93, any one of the N monitoring optical lines 41 can be selected. The mode of connection between the wavelength router 70 and the monitoring optical path 41 is the same as in the first embodiment.
[0047]
That is, the tester 91 is connected to the N monitoring optical lines 41 via the optical switch 93, and is connected to the monitoring optical line 41 selected by the optical switch 93 for monitoring. The optical signal λ ′ is transmitted and received. The optical switch 93 allows the tester 91 to transmit and receive the monitoring optical signal λ ′ to and from any slave device 20.
Note that the slave device 20 is provided with the same reflection means as in the first embodiment, and reflects the monitoring optical signal λ ′ transmitted from the test device 91 and returns it to the test device 91 again. ing.
[0048]
(2) The configuration of the optical line monitoring system that monitors the optical line on the main device side will be described.
As in the first embodiment, the main device 10 of each of the transmission systems 1A, 1B,... 1N includes a monitoring light for monitoring the main device side optical line 40 in addition to the communication optical signals λ of a plurality of wavelengths. The signal λ ″ can be transmitted. The main device 10 of each system is connected to the test control device 92 by a signal line, and transmits a monitoring optical signal λ ″ according to a command from the test control device 92. The specific main device 10 that has been instructed by the test control device 92 transmits a monitoring optical signal λ ″, and this monitoring optical signal λ ″ is output to the monitoring output port 70Qz via the wavelength router 70. Then, the light passes through the optical line 51 and is input to the tester 91.
When the monitoring optical signal λ ″ is input to the tester 91, there is no particular need to use an optical switch for switching the optical path. The transmission of the monitoring optical signal λ ″ of the main device 10 is based on a command from the test control device 92, and the number of the main devices 10 is smaller than the number of the slave devices 20. Therefore, the test control device 92 can easily determine which system main device 10 the input monitoring optical signal λ ″ is from.
[0049]
[Operation of optical line monitoring system]
The operation of the optical line monitoring system A2 according to the second embodiment will be described with reference to FIG.
[0050]
(1) monitoring the optical line on the slave device side;
For example, when monitoring the slave device side optical line 50 (50a, 50b,... 50m) of the transmission system 1A of the system A, the optical path is switched by the optical switch 93, and the monitoring optical signal λ ′ transmitted by the tester 91 is transmitted. It is made to reach only the wavelength router 70 of the transmission system 1A. Then, as in the first embodiment, the monitoring optical signal λ ′ having a wavelength reaching the specific slave device 20 is transmitted, and the slave device 20 (20a, 20b,... 20m) and the wavelength router 70 are transmitted. Are monitored individually for each of the slave device side optical lines 50 (50a, 50b,.
Next, when monitoring the slave device side optical line 50 (50a, 50b,... 50m) of the transmission system 1B of the system B, the optical path is switched by the optical switch 93 and the monitoring optical signal λ ′ transmitted by the tester 91. Reach only the wavelength router 70 of the transmission system 1B. Then, the monitoring optical signal λ ′ is sequentially transmitted to monitor each of the slave device-side optical lines 50 (50a, 50b,..., 50m). The same applies to other systems.
Note that the monitoring optical signal λ ′ transmitted by the tester 91 may be the same as that transmitted to the system A and that transmitted to another system. This is because, since the optical path is switched by the optical switch 93, there is no fear of crosstalk. Therefore, by providing the optical switch 93, it is not necessary to increase the number of monitoring optical signals? 'Transmitted by the tester 91 even if the number of transmission systems to be monitored increases.
[0051]
(2) monitoring of the optical line on the main device side;
For example, when monitoring the main device side optical line 40 of the transmission system 1A of the system A, the main device 10 of the system A sends the monitoring optical signal λ ″ to the wavelength router 70 based on a command from the test control device 92. Send to. Thus, the main device side optical line 40 can be monitored in the same manner as in the first embodiment. The monitoring optical signal λ ″ transmitted by the main device 10 is routed by the wavelength router 70 and reaches the tester 91 via the monitoring output port 70Qz and the optical line 51.
When monitoring the main device side optical line 40 of another system, the test control device 92 issues a command to transmit a monitoring signal λ ″ to the main device 10 of the system to be monitored. Thereby, it is possible to monitor the main device side optical line 40 of an arbitrary system.
[0052]
Thus, according to the optical line monitoring system of the second embodiment, even if the number of transmission systems to be monitored increases, the optical line can be monitored by one optical line monitoring device. Naturally, the wavelength router multiplexes and demultiplexes the optical signal for communication and the optical signal for monitoring, so that it is possible to monitor the optical line for abnormality without causing optical loss due to power branching. Further, since the frequency band of the optical signal for monitoring is different from the frequency band of the optical signal for communication, communication in the transmission system is not hindered.
[0053]
The monitoring optical signal λ ″ for monitoring the main device side optical line 40 described above is supplied to the test equipment via the optical line 51 connected to the monitoring output port 70Qz of the wavelength router 70 for each system. This is a configuration that is input to the input unit 91. Instead of this configuration, as shown in FIG. 9, the monitoring output port 70Qz of the wavelength router 70 includes a reflection unit R2, and reflects the monitoring optical signal λ ″ output to the monitoring output port 70Qz. Is also good.
In the case of this configuration, the reflected monitoring optical signal λ ″ is again received by the main device 10 through the main device side optical line 40 due to the routing characteristics of the wavelength router 70. The main device 10 converts the signal intensity of the received monitoring optical signal λ ″ into an electric signal and transmits it to the test control device 92, and the test control device 92 determines whether or not the main device-side optical line 40 is disconnected. I do.
In this way, the main unit side optical line can be monitored also by providing the reflection unit at the monitoring output port.
[0054]
<< 3rd Embodiment >>
An optical line monitoring system according to a third embodiment will be described with reference to FIG.
In the optical line monitoring system A3 of the third embodiment, the main device side optical line 40 also serves as a monitoring optical line.
[0055]
[Configuration of optical line monitoring system]
The optical line monitoring system A3 according to the third embodiment is similar to the optical line monitoring system A1 according to the first embodiment in that the optical lines (the sub-device-side optical line 50, the main device-side optical line, 40) is monitored.
Since the transmission system 1 has the same configuration and function as the transmission system 1 of the first embodiment, the same reference numerals are given to the same elements and members, and description thereof will be omitted.
Similarly, for the optical line monitoring system A3, the same elements and members as those of the optical line monitoring system A1 of the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.
[0056]
(1) The configuration of an optical line monitoring system that monitors an optical line on a slave device side will be described.
In the third embodiment, the tester 91 is connected to the wavelength router 70 via the main device 10 and the optical line 42. The tester 91 is configured to transmit and receive the monitoring optical signal λ ′ via the optical line 42. Therefore, the monitoring optical path 41 (see FIG. 1 and the like) in the first embodiment and the second embodiment does not exist.
[0057]
The main device 10 includes a multiplexing / demultiplexing unit for multiplexing / demultiplexing the monitoring optical signal λ ′ and the communication optical signal λ transmitted by the main device 10 (see FIG. 11). This multiplexing / demultiplexing unit has a filter F3, and multiplexes (superimposes) the monitoring optical signal λ ′ transmitted from the tester 91 and the communication optical signal λ transmitted from the main unit 10 with the filter F3. Then, the combined optical signal (λ · λ ′) is guided to the main device side optical line 40. The multiplexing / demultiplexing unit separates the monitoring optical signal λ ′ (reflected signal) from the slave device 20 and the communication optical signal λ by the filter F3, and transmits the communication optical signal λ to the transmitting / receiving unit. 11 to guide the monitoring optical signal λ ′ to the optical line 42 (that is, the tester 91).
[0058]
As shown in FIG. 12, the filter F3 of the multiplexing / demultiplexing means includes a frequency band of the communication optical signal λ (λa, λb... Λm) and a monitoring optical signal λ ′ (λ′a λ′b. λ′m) is separated from the frequency band according to the wavelength.
[0059]
In addition, the configurations of the slave device 20, the main device side optical line 40, the wavelength router 70, the optical line 51, the tester 91, the test control device 92, and the like are the same as those of the first embodiment.
[0060]
(2) The configuration of the optical line monitoring system that monitors the optical line on the main device side will be described.
The optical line monitoring system A3 according to the third embodiment differs from the first embodiment and the like in that the tester 91 transmits a monitoring optical signal λ ″ for monitoring the main device side optical line 40. The wavelength of the monitoring optical signal λ ″ is selected such that it transmits through the filter F3 of the multiplexing / demultiplexing means and is routed to the monitoring output port 70Qz of the wavelength router 70. The configuration of the wavelength router 70, the optical line 51, and the like is the same as the configuration of the first embodiment. The monitoring optical signal λ ″ in the third embodiment is assigned an optical signal of an unused wavelength (vacant wavelength) among the monitoring optical signal λ ′.
[0061]
[Operation of optical line monitoring system]
The operation of the optical line monitoring system A3 according to the third embodiment will be described with reference to FIG.
[0062]
(1) monitoring the optical line on the slave device side;
In the third embodiment, the monitoring optical signal λ ′ transmitted by the tester 91 is input to the wavelength router 70 via the optical line 42, the main device 10 (the filter F3), and the main device side optical line 40, and According to the routing characteristics of the router 70, the light reaches the specific slave device 20 through the specific slave device side optical line 50. The monitoring optical signal λ ′ arriving at the slave device 20 is reflected by the reflecting means, is again routed by the wavelength router 70 through the slave device-side optical line 50, and is sent to the master device-side optical line 40 and the master device 10 (filter F 3). Are received by the tester 91 via the optical line 42. As in the first embodiment, the presence or absence of an abnormality such as a disconnection of the slave device-side optical line 50 is monitored based on the intensity level of the received monitoring optical signal λ ′ and the length of the returning time. The control of the test machine 91 and the determination of the presence or absence of an abnormality are performed by the test control device 92.
[0063]
(2) monitoring of the optical line on the main device side;
In the third embodiment, a tester 91 for monitoring the main device side optical line 40 transmits a monitoring optical signal λ ″. The monitoring optical signal λ ″ transmitted by the tester 91 is input to the wavelength router 70 via the optical line 42, the main device 10 (the filter F3), and the main device side optical line 40, and is routed by the wavelength router 70. It is output to the monitoring output port 70Qz. The tester 91 receives the signal from the monitoring output port 70Qz via the optical line 51. Based on the intensity level of the received monitoring optical signal λ ″ and the length of the return time, the presence or absence of an abnormality such as a disconnection in the main device side optical line 40 is monitored. The control of the test machine 91 and the determination of the presence or absence of an abnormality are performed by the test control device 92.
[0064]
According to the optical line monitoring system of the third embodiment, in addition to the effects of the optical line monitoring system of the first embodiment, a dedicated optical line (monitoring optical line) connecting the tester and the wavelength router is provided. This has the effect of making it unnecessary. For example, it is advantageous when the distance between the tester and the wavelength router is greater than that between the tester and the main device.
Further, in the case of the third embodiment, since the monitoring optical signal for monitoring the slave device side optical line passes through the master device side optical line, the monitoring of the slave device side optical line and the master device side optical line are simultaneously performed. Monitoring can also be performed.
[0065]
As in the first embodiment, a reflection unit R2 is provided in the monitoring output port 70Qz (see FIG. 13), and the monitoring optical signal λ ″ is reflected by the reflection unit R2 and returns to the wavelength router 70, where The signal may be received by the tester 91 through the side optical line 40. In this case, the optical line 51 becomes unnecessary. Therefore, this is advantageous when the distance between the tester 91 and the wavelength router 70 is large.
[0066]
<< 4th Embodiment >>
An optical line monitoring system according to the fourth embodiment will be described with reference to FIG.
In the fourth embodiment, as in the second embodiment, a plurality of transmission systems are monitored by one optical line monitoring system A4.
[0067]
[Configuration of optical line monitoring system]
The optical line monitoring system A4 of the fourth embodiment monitors the slave device side optical line 50 and the main device side optical line 40, similarly to the optical line monitoring system A3 of the third embodiment. However, as in the second embodiment, there are N transmission systems 1 from system A to system N.
Since each of the transmission systems 1A, 1B,... 1N has the same configuration and function as the transmission system 1 of the third embodiment, the same elements and members are denoted by the same reference numerals, and description thereof is omitted. I do.
Similarly, for the optical line monitoring system A4, the same elements and members as those of the optical line monitoring system A3 of the third embodiment are denoted by the same reference numerals, and description thereof is omitted.
[0068]
(1) The configuration of an optical line monitoring system that monitors an optical line on a slave device side will be described.
The optical line monitoring device 90 according to the fourth embodiment has an optical switch 93 in addition to the tester 91 and the test controller 92. This is the same as the second embodiment, but different from the third embodiment. The optical switch 93 is connected to N main devices 10 from the system A to the system N by N individual optical lines 42. The optical switch 93 is an optical path switch that switches an optical path based on a command from the test control device 92. With this optical switch 93, any one of the N optical lines 42 can be selected. The connection between the main device 10 and the optical line 42 is the same as in the third embodiment.
[0069]
That is, the tester 91 is connected to the N main units 10 from the system A to the system N via the optical switch 93, and sends a monitoring optical signal to the main unit 10 of the system selected by the optical switch 93. λ ′ is transmitted (received). The optical switch 93 allows the tester 91 to transmit and receive the monitoring optical signal λ ′ to and from the slave device 20 (20a, 20b,..., 20m) of an arbitrary system.
Note that the slave device 20 is provided with the same reflection means as in the first to third embodiments, reflects the monitoring optical signal λ ′ transmitted from the test device 91 and returns it to the test device 91 again. It has become. Each of the main units 10 includes a multiplexing / demultiplexing unit as in the third embodiment. Can be multiplexed / demultiplexed.
[0070]
(2) The configuration of the optical line monitoring system that monitors the optical line on the main device side will be described.
The transmission of the monitoring optical signal λ ″ for monitoring the main device side optical line 40 of the transmission system 1 (1A, 1B,... 1N) of each system is performed by the tester 91 (as the main device 10 performs). Good). The monitoring optical signal λ ″ passes through the same route as the monitoring optical signal λ ′ to the wavelength router 70. Then, according to the routing characteristics of the wavelength router 70, the signal is output to the monitoring output port 70Qz. To which wavelength router 70 the monitoring optical signal λ ″ is transmitted is controlled by the test controller 92 via the optical switch 93. The monitoring optical signal λ ″ output to the monitoring output port 70Qz passes through the optical line 51 and is input (received) to the tester 91.
When the monitoring optical signal λ ″ is input to the tester 91, there is no particular need to use an optical switch for switching the optical path. The transmission of the monitoring optical signal λ ″ is based on a command from the test control device 92, and the number of the main device side optical lines 40 is smaller than the number of the slave device side optical lines 50. For this reason, the test control device 92 can easily determine which system the input monitoring optical signal λ ″ belongs to.
Incidentally, the monitoring optical signal λ ″ in the fourth embodiment is assigned an optical signal of an unused wavelength (open wavelength) in the monitoring optical signal λ ′.
[0071]
[Operation of optical line monitoring system]
The operation of the optical line monitoring system A4 according to the fourth embodiment will be described with reference to FIG.
[0072]
(1) monitoring the optical line on the slave device side;
For example, when monitoring the slave device side optical line 50 (50a, 50b,... 50m) of the transmission system 1A of the system A, the optical path is switched by the optical switch 93, and the monitoring optical signal λ ′ transmitted by the tester 91 is transmitted. It is made to reach only the wavelength router 70 of the transmission system 1A. Then, as in the first embodiment and the like, the monitoring optical signal λ ′ having a wavelength that reaches the specific slave device 20 is sequentially transmitted, and the slave device 20 (20a, 20b,. Each of the slave device-side optical lines 50 (50a, 50b,..., 50m) individually connecting to the router 70 is monitored.
Next, when monitoring the slave device side optical line 50 (50a, 50b,... 50m) of the transmission system 1B of the system B, the optical path is switched by the optical switch 93, and the monitoring optical signal λ ′ transmitted by the tester 91. Arrives at the wavelength router 70 of the transmission system 1B. Then, the monitoring optical signals λ ′ are sequentially transmitted, and each of the slave device side optical lines 50 (50a, 50b,..., 50m) of the system B is monitored. The same applies to other systems.
Note that the monitoring optical signal λ ′ transmitted by the tester 91 may be the same as that transmitted to the system A and that transmitted to another system. This is because, since the optical path is switched by the optical switch 93, there is no fear of crosstalk. Therefore, by providing the optical switch 93, it is not necessary to increase the number of monitoring optical signals? 'Transmitted by the tester 91 even if the number of transmission systems to be monitored increases.
[0073]
(2) monitoring of the optical line on the main device side;
For example, when monitoring the main device side optical line 40 of the transmission system 1A of the system A, the optical path of the optical switch 93 is switched based on a command from the test control device 92, and the tester 91 changes the monitoring optical signal λ ″. Is transmitted to the wavelength router 70 of the system A. Thereby, similarly to the case of the third embodiment and the like, the monitoring of the main device side optical line 40 of the system A can be performed. The monitoring optical signal λ ″ transmitted by the tester 91 is routed by the wavelength router 70 and reaches the tester 91 via the monitoring output port 70Qz and the optical line 51.
When monitoring the main device side optical line 40 of another system, the test control device 92 switches the optical path of the optical switch 93 to the system to be monitored and issues a command to transmit the monitoring signal λ ″. Thereby, it is possible to monitor the main device side optical line 40 of an arbitrary system.
[0074]
As described above, according to the optical line monitoring system of the fourth embodiment, even if the number of transmission systems to be monitored increases, the optical line can be monitored by one optical line monitoring device. Naturally, the wavelength router multiplexes and demultiplexes the optical signal for communication and the optical signal for monitoring, so that it is possible to monitor the optical line for abnormality without causing optical loss due to power branching. Further, since the frequency band of the optical signal for monitoring is different from the frequency band of the optical signal for communication, communication in the transmission system is not hindered.
[0075]
The above-described monitoring optical signal λ ″ for monitoring the main device side optical line 40 is input to the tester 91 via the optical line 51 connected to the monitoring output port 70Qz of the wavelength router 70. It is. Instead of this configuration, as shown in FIG. 15, the monitoring output port 70Qz of the wavelength router 70 includes a reflection unit R2, and reflects the monitoring optical signal λ ″ output to the monitoring output port 70Qz. Is also good.
In the case of this configuration, the reflected monitoring optical signal λ ″ passes through the main device side optical line 40, the main device 10, and the optical switch 93 again according to the routing characteristics of the wavelength router 70, and is received by the tester 91. You. The test control device 92 determines the presence or absence of an abnormality such as the disconnection of the main device side optical line 40 and the location of the abnormality based on the signal level of the monitoring optical signal λ ″ received by the tester 91.
In this way, the main unit side optical line can be monitored also by providing the reflection unit at the monitoring output port.
[0076]
The optical line monitoring system of the present invention described above is not limited to the above-described embodiments of the present invention, but can be appropriately modified and implemented within the scope of achieving the objects and effects of the present invention.
For example, an optical line monitoring system that only monitors the optical line on the slave device side may be used. Further, two types of reflection means in the slave device may be mixed in one transmission system. Further, a monitoring output port with and without a reflection unit attached thereto may be mixed in one transmission system. The reflection unit that reflects the monitoring optical signal that monitors the slave device-side optical line may be installed in the slave device, or may be installed at a position close to the slave device in the slave device-side optical line. Good. Similarly, the multiplexing / demultiplexing means may be installed in a position close to the main device in the optical path on the main device side, in addition to being incorporated in the main device.
[0077]
【The invention's effect】
ADVANTAGE OF THE INVENTION According to the optical-line monitoring system of this invention, an optical line can be monitored, without causing the optical loss by a power branch, and producing no trouble in communication.
Further, installation and handling of the system is easy.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a configuration of an optical line monitoring system according to a first embodiment of the present invention, together with a configuration of a transmission system.
FIG. 2 is a diagram illustrating functions of a wavelength router.
FIG. 3 is a diagram illustrating a configuration of a reflection unit. (A) is a configuration provided with a reflection unit, and (b) is a configuration in which a filter reflects a monitoring optical signal.
FIG. 4 is a diagram illustrating characteristics of a filter F1 in FIG.
FIG. 5 is a diagram illustrating characteristics of a filter F2 in FIG.
FIG. 6 is a diagram illustrating characteristics of a wavelength router.
FIG. 7 is a diagram showing a configuration of a modification of the optical line monitoring system of FIG. 1;
FIG. 8 is a diagram illustrating a configuration of an optical line monitoring system according to a second embodiment of the present invention, together with a configuration of a transmission system.
FIG. 9 is a diagram illustrating a configuration of a modification of the optical line monitoring system of FIG. 8;
FIG. 10 is a diagram illustrating a configuration of an optical line monitoring system according to a third embodiment of the present invention, together with a configuration of a transmission system.
FIG. 11 is a diagram illustrating a configuration of a multiplexing / demultiplexing unit provided in a main device.
FIG. 12 is a diagram illustrating characteristics of a filter F3 in FIG. 11;
FIG. 13 is a diagram showing a configuration of a modification of the optical line monitoring system of FIG. 10;
FIG. 14 is a diagram illustrating a configuration of an optical line monitoring system according to a fourth embodiment of the present invention, together with a configuration of a transmission system.
FIG. 15 is a diagram showing a configuration of a modified example of the optical line monitoring system of FIG.
FIG. 16 is a diagram showing a configuration of a conventional optical line monitoring system together with a configuration of a transmission system.
FIG. 17 is a diagram showing a configuration of a conventional optical line monitoring system different from FIG. 16 together with a configuration of a transmission system.
[Explanation of symbols]
A Optical line monitoring system (A1, A2, A3, A4)
90 Optical line monitoring device
91 Testing machine (Multi-wavelength compatible testing machine)
92 Test control device
93 Optical Switch
1 Transmission system (1A, 1B, 1N)
10 Main device
20 Dependent devices
40 Main device side optical line (optical line)
41 Optical Line
42 optical line
50 Dependent equipment side optical line (optical line)
51 Optical Line
70 wavelength router
70P input port
70Q output port
70Qz monitoring output port
F1 filter (in the slave device)
F2 filter (in the slave unit)
F3 filter (in the main unit)
R1 Reflector (in the slave device)
R2 reflector

Claims (5)

An optical line monitoring system that monitors an optical line in a transmission system that performs optical communication by connecting a main device and a plurality of subordinate devices via an optical line via a multiple-input multiple-output passive wavelength router,
The optical line monitoring system includes: (1) a tester that transmits and receives monitoring optical signals of a plurality of wavelengths for monitoring a slave device side optical line that connects the slave device and the wavelength router among the optical lines. provided with a optical line monitoring apparatus comprising a test controller for controlling the tester, a reflecting means for reflecting (2) each of the optical signal monitoring in the dependent apparatus of the transmission system, furthermore, (3 A) a monitoring light beam between any input port of the input port of the wavelength router connected to the main device of the wavelength router and any input port different from the input port connected to the main device; By the road,
The tester: (1) transmits the monitoring optical signal to the slave device via the wavelength router, and (2) transmits the monitoring optical signal reflected by a reflection unit included in the slave device. Received again through the wavelength router,
Monitoring the slave device side optical line,
An optical line monitoring system characterized by the following. The wavelength router has a monitoring output port for monitoring a main device side optical line connecting the main device and the wavelength router to an output port portion on a side to which the plurality of slave devices are connected. The optical device according to claim 1, wherein the optical signal transmitted from the main device is transmitted as the monitoring optical signal to the monitoring output port, thereby monitoring the main device side optical line. Optical line monitoring system. The monitoring optical signal transmitted from the main device to the monitoring output port is input to the main device or the testing machine by any of the following means, and the monitoring of the main device side optical line is performed. The optical line monitoring system according to claim 2, wherein the monitoring is performed.
(1) The monitoring output port includes a reflection unit, and reflects the monitoring optical signal transmitted from the main device by the reflection unit, and transmits the monitoring optical signal to the main device via the wavelength router and the main device side optical line. Means to enter.
(2) A means for connecting the monitoring output port and the tester with an optical line, and inputting the monitoring optical signal transmitted from the main unit to the tester via the optical line. The optical line monitoring system according to any one of claims 1 to 3, wherein the reflection unit provided in the slave device is a next reflection unit.
The slave device has a filter for multiplexing / demultiplexing optical signals in a plurality of wavelength bands, and this filter allows a monitoring optical signal transmitted from the optical line monitoring device and a communication optical signal transmitted from the main device. And the monitoring optical signal transmitted from the optical line monitoring device is reflected by the reflection unit, and the reflected optical signal is guided to the original optical line through the filter. Reflection means for multiplexing with the communication optical signal (λ) transmitted and received by the main device. The main device and the tester are connected by an optical line, and the main device is configured to multiplex / demultiplex a communication optical signal transmitted / received by the main device and a monitoring optical signal transmitted / received by the test device. The main unit side optical line also functions as the monitoring optical line, and the tester transmits and receives a monitoring optical signal for monitoring the slave unit side optical line via the main unit side optical line. The optical line monitoring system according to any one of claims 1 to 4 , wherein:

Images