JP2003264509A - Module for optical communication, transmitting side module for optical communication, receiving side module for optical communication and interruption recovery method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a module for optical communication which quickly interrupts high output power when a connector is attached or detached or when a fiber is interrupted, allows a maintenance person to recognize the leakage of high output power even when an interrupting function fails and detects bending before the high output power is lost to interrupt the high output power by using a detection method sensitive to fiber bending. <P>SOLUTION: This module 1 for communication is provided with an input port 3 and an output port 4, used for optical fiber communication, wherein information communication light is inputted from the input port 3 and outputted from the output port 4, and provided with an optical coupler 5, a light source 6 for excitation and a visible light source 7. One end of the optical coupler 5 is connected to the input port 3 and the other end is connected to the output port 4, the light source 6 for excitation and the visible light source 7 are connected to the output port 4 side of the optical coupler 5, and excitation light and visible light are outputted from the input port 3. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical communication module used in an optical fiber communication system and a method for recovering from interruption of the optical fiber communication system.

[0002]

2. Description of the Related Art In recent years, with the invention of an optical amplifier and its introduction into the market, the demand for a signal-to-noise ratio (SNR) has been significantly eased, and an ultrahigh-speed optical transmission system exceeding 10 Gbit / s has been put into practical use. It is introduced worldwide. Further, a linear repeater capable of collectively amplifying a certain wavelength band is introduced by utilizing the wide band property of the optical amplifier, and further cost reduction is achieved.

On the other hand, the introduction of this optical amplifier automatically increased the optical power input to the optical fiber. here,
In the case of a single wavelength, the maximum optical power is usually 17 dBm (50 mW), and in the case of wavelength multiplexing, the optical power of an integral multiple thereof is easily input to the fiber. And from a laser safety standard, an optical fiber system is said to be intrinsically safe if light is trapped in the fiber.

However, if light leaks from the optical fiber once the connector is detached or the fiber is broken, it consumes energy and adversely affects the surroundings. IEC (International Electrotechni
cal commission), IEC60825-2 (Safety of laser
products−part2 Safety of optical fiber communicat
Ion system) has been established and "Hazard level: potential exposure level" from the above viewpoint.
Is defined and safety standards for maintenance and service are established.

In the above-mentioned safety standards, a function APR (Automatic Power Reduction) for promptly reducing the power to a certain amount or less when a connector is attached or detached or a fiber is cut is described as a required function. Received a request for this feature,
ITU-T (International Telecommunication Union-Teleco
mmunication), G.664 (Optical safety
procedures and requirements for optical transport
systems).

In this recommendation, the procedure ALS (Automatic Laser Shutdo) for a system in which the system automatically and promptly shuts off the main signal light when the connector is attached or detached or the fiber is cut
wn) is shown. The safety of the optical transmission system using the optical amplifier is secured by the above two recommendations of IEC and ITU-T.

On the other hand, research on distributed amplification systems has begun to be carried out with the aim of further increasing the distance and reducing the cost. In particular, the technique of distributed amplification using the Raman amplification principle in a transmission line (optical fiber) has been rapidly launched. This technique can significantly reduce the number of costly electrical regenerators and eliminates the need to inject high main signal power into the fiber, resulting in undesirable effects such as nonlinear optical effects on the main signal. There is an advantage that can be avoided.

In the Raman distributed amplification technique, very high pumping light (usually 100 nm shorter than the main signal light wavelength) is injected into the optical fiber from the receiver side, and the entire transmission line becomes an amplification medium. However, there is a feature. On the other hand, in the conventional optical amplifier, the pumping light (wavelength 1480 nm or 980 nm) is terminated in the amplifier, and the pumping light does not propagate to the transmission line.

[0009]

Due to the above-mentioned increase in the number of wavelength multiplexes or injection of a transmission line of high power pumping light by distributed amplification, the optical fiber may be
Power of several W will be incident. Given these levels of optical power, no additional safety precautions can be taken as maintenance work.

Further, without noticing that the light from the optical fiber is being radiated, the high-power pumping light is continuously radiated, and the function of promptly lowering the power below a certain amount does not work,
Excessive energy may be consumed, and the conventional light blocking function specification does not assume that the blocking function itself is out of order. If the connector disconnection / fiber disconnection (optical fiber disconnection) occurs during the high output power operation as described above and the blocking function is broken, high output energy is immediately released from the optical fiber end face. If it is not shut off, high-power energy will be radiated in vain, and extra energy will be consumed.

Further, even during maintenance work and during operation, optical power is lost due to uncleaned connectors or fiber bending, and energy is unnecessarily lost due to heat generation. For connectors,
Fewer cases when cleaning and other tasks are complete. In addition, the fiber bending is the fiber that connects the devices in the station (building),
There is a possibility of occurrence with a considerably small radius of curvature even in the transmission line, such as a closure.

When a bend occurs at a small local radius, the loss of light is usually increased and the light cannot be transported to its destination.
The light lost by the loss is leaking at the bending point, and the fiber carries light of several W class, and if the optical fiber itself or its coating contains a light absorbing medium. However, there is a possibility that heat will be generated at the bending point, and this heat generation will consume extra energy and reduce the intensity of propagating light.

The present invention has been made in the background as described above, and it is intended to cut off high output power promptly when a connector is attached / detached or the fiber is cut, and even if the cutoff function is broken, the maintenance person is lit from the fiber. By recognizing that there is a leak and using a detection method that is sensitive to fiber bend, the bend is detected and the high output power is cut off before energy is lost due to heat generated by the high output power. Provided is an optical communication module capable of performing the above.

[0014]

An optical communication module according to claim 1 of the present invention comprises a fiber input port (input port 3) and a fiber output port (output port), and an optical fiber for information communication. In a module for optical communication used for optical fiber communication in which a signal is input from the fiber input port and output from the fiber output port,
The optical communication module (optical communication module 1) is
An optical directional coupler (optical coupler 5), a distributed amplification pumping light source (pumping light source 6), and a visible light source (visible light source 7) are provided, and the directional coupler is connected to the fiber input port at one end. Connected, the fiber output port is connected to the other end, the excitation distribution amplification light source and the visible light source are connected to the output port side of the directional coupler, pumping light and visible light from the fiber input port It is characterized by being output.

The optical communication module according to claim 2 of the present invention is the optical communication module according to claim 1, wherein
It is characterized by comprising means for cutting off the excitation distribution amplification light source, and a control signal interface (cut-off control interface 9) for controlling the excitation distribution amplification cut-off means.

An optical communication module according to claim 3 of the present invention comprises a fiber input port and a fiber output port, and an optical signal for information communication is input from the fiber input port and from the fiber output port. In the optical communication module used for output optical fiber communication, the optical communication module is composed of a transmission side module (transmission side module 21) and a reception side module (reception side module 26), and the transmission side module is An optical directional coupler (optical coupler 22) and a fiber bending detection light source (fiber bending detection light source 23) are provided,
The optical directional coupler has one end connected to the fiber input port (input port 40) and the other end connected to the fiber output port (output port 41), and the fiber bend detection light source is connected to the directional coupler. Connected to the fiber input port side, the reception side module includes an optical directional coupler (optical coupler 27), a pumping light source for pumping distribution amplification (pumping light source 28), and a fiber bend detecting optical receiver (fiber bender). Detecting light receiver 31) and means for cutting off the pumping light source for pumping distribution amplification (pumping light source blocking / restoring means 29)
Wherein the directional coupler has one end connected to the fiber input port (input port 42) and the other end connected to the fiber output port (output port 43),
The excitation light source for pumping distribution amplification and the optical receiver for detecting fiber bending are connected to the fiber output port side of the directional coupler, the optical receiver for fiber bending detection and the excitation light source blocking means for pumping distribution amplification. Are connected by a control line.

In the optical communication module according to claim 4 of the present invention, the transmitting module modulates the data generator (data generator 25) and the fiber bend detection light source with the data (data modulating means). 24), the reception side module is provided with means for analyzing electrical signal data output from the fiber bend detection optical receiver, and based on the analysis result, the excitation light source cutoff means for excitation distribution amplification is provided. Means for controlling and shutting off, and means for controlling and shutting off the pumping light source blocking means for pumping distribution amplification based on the normality of the analysis result (fiber bend detecting optical receiver 3
1, a data analyzer 32) is provided.

An optical communication module according to claim 5 of the present invention is the optical communication module according to claim 3 or 4, wherein the receiving side module emits visible light to the optical directional coupler. It is characterized by comprising a visible light source.

An optical communication module according to claim 6 of the present invention comprises a fiber input port and a fiber output port, and an information communication optical signal is input from the fiber input port and output from the fiber output port. In the optical communication module used for optical fiber communication, the optical communication module includes a transmission side module (transmission side module 50) and a reception side module (reception side module), and the transmission side module is the first module. Optical directional coupler (optical coupler 22), second optical directional coupler (optical coupler 27), fiber bending detection light source (fiber bending detection light source 23), and pump distribution amplification light source (pumping) Light source 28), a fiber bend detection optical receiver (fiber bend detection optical receiver 31), and the pump distribution amplification pump light source. Means (pumping light source cutoff / restoration means 29), a fiber bend detection light source is connected to the fiber input port (input port 40) side of the first optical directional coupler, and the other end has the first Two optical couplers are connected, and the pumping light source for pumping distribution amplification is a fiber output port (output port 43) of the second directional coupler.
And the receiving side module is connected to a third optical directional coupler (optical coupler 22), a fourth optical directional coupler (optical coupler 27), and a fiber bending detection light source (fiber bending detection). Light source 23), a distribution amplification pumping light source (pumping light source 28), a fiber bending detection optical receiver (fiber bending detection optical receiver 31), and means for cutting off the pumping distribution amplification pumping light source ( Excitation light source cutoff / recovery means 2
9), the fiber bend detection light source is connected to the fiber output port (output port 43 ′) side of the third optical directional coupler, and the fourth optical coupler is connected to the other end, The pumping light source for pumping distribution amplification is connected to the fiber input port (input port 40 ') side of the fourth directional coupler.

An optical communication module according to claim 7 of the present invention is the optical communication module according to claim 6, wherein
The transmission side module and the reception side module respectively include a data generator (data generator 25) and means for modulating the fiber bend detection light source with the data (data modulation means 24), and the transmission side module and The receiving side module is provided with means (data analyzer 32) for analyzing electric signal data obtained by photoelectrically converting light output from the modules to which the fiber bend detecting optical receivers face each other, and based on the analysis result. And means for controlling and shutting off each of the pumping light source blocking means for pumping distribution amplification, and means for controlling and shutting off the pumping light source blocking means for pumping distribution amplification based on the normality of the analysis result. It is characterized by

The optical communication module according to claim 8 of the present invention is the optical communication module according to claim 6 or 7, wherein the receiving side module and the transmitting side module are respectively the optical directionality. The coupler is provided with a visible light source (visible light source 30) for emitting visible light.

An optical communication transmission side module (transmission side module 21) according to claim 9 of the present invention comprises a fiber input port and a fiber output port, and an information communication optical signal is input from the fiber input port. In the optical communication transmission side module used for optical fiber communication output from the fiber output port, an optical directional coupler and a fiber bending detection light source are provided, and the optical directional coupler is provided. The fiber input port is connected to one end, the fiber output port is connected to the other end, and the fiber bend detection light source is connected to the input port side of the directional coupler.

An optical communication transmission side module according to a tenth aspect of the present invention is the optical communication transmission side module according to the ninth aspect, wherein a data generator for generating predetermined data and the fiber bend detection light source are provided. It is characterized by comprising means for modulating the light emitted from the device by the data.

An optical communication transmitting side module according to claim 11 of the present invention comprises a fiber input port and a fiber output port, and an information communication optical signal is input from the fiber input port, and the fiber output port. In a transmission side module for optical communication (transmission side module 50) used for optical fiber communication output from a first optical directional coupler (optical coupler 22) and a second optical directional coupler (optical coupler 27) and a light source for detecting fiber bending,
A distributed amplification pumping light source, a fiber bend detection optical receiver, and means for cutting off the distributed amplification pumping light source, wherein the first optical directional coupler has the fiber input port at one end, The second optical directional coupler is connected to the other end, and the distributed amplification pumping light source is connected to the fiber output port side of the second optical coupler.

According to a twelfth aspect of the present invention, there is provided an optical-communication transmitting-side module according to the eleventh aspect, wherein the optical-transmitting-side module emits light from a data generator that generates predetermined data and the fiber bend detection light source. Means for modulating light with the data, means for analyzing electrical signal data output from the fiber bend detection optical receiver, and the pumping light source for pumping distribution amplification based on the output of the receiver. The present invention is characterized by comprising means for controlling and shutting off the shutoff means, and means for controlling and shutting off the pumping light source for pumping distribution amplification based on the normality of the analysis data.

An optical communication transmission side module according to a thirteenth aspect of the present invention is the optical communication module according to the eleventh aspect or the twelfth aspect, in which the transmission side module is visible through the second optical directional coupler. It has a visible light source that emits light.

An optical communication reception side module (reception side module 26) according to claim 14 of the present invention comprises a fiber input port and a fiber output port, and an information communication optical signal is input from the fiber input port. In the optical communication receiving side module used for optical fiber communication output from the fiber output port, an optical directional coupler, a fiber bending detection light source, a distributed amplification pumping light source, and a fiber bending detection light. A receiver and means for cutting off the distributed amplification pumping light source, wherein the directional coupler has one end connected to the fiber input port and the other end connected to the fiber output port, and the pumping distribution An amplification pumping light source and the fiber bend detection optical receiver are connected to the fiber output port side of the directional coupler,
The fiber bend detecting optical receiver and the excitation light source blocking means are connected by a control line.

According to a fifteenth aspect of the present invention, in the optical communication receiving side module, in the optical communication receiving side module, the electric signal data outputted from the fiber bend detecting optical receiver is analyzed. Means for controlling and cutting off the excitation light source blocking means based on the output of the receiver, and means for controlling the excitation light source blocking means based on the normality of the analysis data to restore the interruption. It is characterized by including.

The optical communication receiver module according to claim 16 of the present invention is the optical communication receiver module according to claim 14 or 15, wherein visible light is made incident on the optical directional coupler. A light source is provided.

An optical communication receiving side module (receiving side module 51) according to claim 17 of the present invention comprises a fiber input port and a fiber output port, and an information communication optical signal is input from the fiber input port. In the reception module for optical communication used for optical fiber communication output from the fiber output port, a first optical directional coupler (optical coupler 22) and a second optical directional coupler (optical coupler ), A fiber bending detection light source, a distributed amplification pumping light source, a fiber bending detection light receiver, and means for cutting off the distributed amplification pumping light source, and the first optical directional coupler. The one end is connected to the fiber output port, and the other end is connected to the second optical directional coupler, and the distributed amplification pumping light source is provided on the fiber input port side of the second optical coupler. Characterized in that it is connected.

The optical communication receiving side module according to claim 18 of the present invention is the optical communication receiving side module according to claim 17, in which a data generator for generating predetermined data and the fiber bend detecting light source are provided. Means for modulating the light emitted from the device by the data, and means for analyzing electric signal data output from the fiber bend detection optical receiver, and the excitation distribution amplification based on the output of the receiver. And a means for controlling and shutting off the pumping light source blocking means for controlling the pumping light source, and a means for controlling and shutting off the pumping light source blocking means for pumping distribution amplification based on the normality of the analysis data.

An optical communication receiving side module according to claim 19 of the present invention is the optical communication receiving side module according to claim 17 or 18, wherein the second optical directional coupler is provided in a transmission line. And a visible light source that emits visible light.

An interruption recovery method according to a twentieth aspect of the present invention is directed to a recovery method of an optical fiber communication system, which comprises a fiber input port and a fiber output port, and an optical signal for information communication receives the fiber input. Input from the port and output from the fiber output port,
In a method for recovering from interruption of an optical fiber communication system composed of a transmission side module and a reception side module, a step of generating predetermined data by a data generator and a step of modulating light emitted from a fiber bend detection light source with the data. A process of emitting the modulated light from the transmitting module, a process of entering the modulated light into the receiving module, and an electrical output of the fiber bend detection optical receiver based on the incident light. The process of analyzing the signal data,
Based on this analysis result, it has a step of controlling and cutting off the distribution amplification pumping light source blocking means, and a step of controlling the distribution amplification pumping light source blocking means on the basis of the normality of the analysis result to restore blocking. It is characterized by

[0034]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. <First Embodiment> FIG. 1 is a block diagram showing an example of the arrangement of an optical communication module according to the first embodiment of the present invention. In this figure, the optical communication module 1 may be provided outside the transmission device 2 in the optical fiber communication system, or may be included (arranged) in the transmission device.

In the communication module 1, the information communication light is transmitted through the optical fiber 11 and the input port 3 through which the excitation light and the visible light are superimposed and the information communication light is transmitted through the optical fiber 12. An output port 4 for emitting to the device 2 is provided. Here, the input / output is a name given to the light of the wavelength for information communication, that is, the propagation direction of the information communication light.

Further, the communication module 1 has an optical coupler (directional coupler) 5 therein, a pumping light source 6 for pumping distribution amplification for emitting pumping light for amplifying information communication light, and visible light. It further comprises a visible light source 7 for emitting light, an excitation light source blocking unit 8, and a blocking control interface 9 for controlling the excitation light blocking unit 8. The input port 3 is simply connected to the optical coupler 5, the output port 4 is connected to the other end, and the excitation light source 6 and the visible light source 7 are connected to the output port 4 side at the other end. .

Here, it is assumed that the connector of the optical fiber 11 is attached / detached at the fiber input point, that is, the fiber input port 3. In normal operation, a loss of signal (LOS) is detected in the transmission device 2 behind the fiber output port 4 of the communication module 1. As a result, when the transmission device 2 detects the light interruption,
The LOS signal is output to the communication module 1.

The LOS signal from the transmission device 2 reaches the cutoff control interface 9 of the communication module 1 via the control line 10. The LOS signal which is the control information may simply be a DC voltage of "0" or "1", and the simplest protocol can be adopted. When the LOS signal is input from the cutoff control interface 9, the communication module 1 cuts off the excitation light source 6.

Normally, by shutting off the excitation light source 6, it is possible to prevent the consumption of extra energy. Also,
The LOS signal is transmitted from the transmission device 2 in the form of LOS detection even with respect to a fiber bend generated in the transmission path of the optical fiber 11 or the optical fiber 12, so that energy consumption due to heat generation is prevented. It is thought that you can do it.

On the other hand, if the disconnection function of the transmission device 2 is broken when the connector is attached or detached, the maintenance person cannot detect the state in which the high output power light is radiated, and the extra energy is consumed. Becomes Therefore, in the communication module 1 of the present invention, the visible light emitted from the visible light source 7 is excited by the optical coupler 5 into the excitation light source 6.
Is emitted from the input port 3 to the optical fiber 11 after being superimposed on the excitation light emitted from the optical fiber 11. Thereby, the maintenance person who attaches / detaches the connector can recognize that light is leaking from the optical fiber by the visible light emitted from the visible light source 7 emitted from the input port 3 and can block the high output power light. You can

There is a technique called core wire contrast in the conventional technique,
It is used as a technique for selecting a desired core wire from a large number of fiber core wires. Normally, the 1550 nm band is used because of its small loss, but there is also a proposal to use visible light for improving operability (Japanese Patent Laid-Open No. 2000-88).
704, Utility Model No. 3024450). However, in the conventional technology, since the communication module 1 has the input port 3 for the optical fiber 11 even though the input port 3 for the optical fiber 11 is used, the communication module 1 is used for distinguishing the core wire at the time of construction work without service. It does not have an output port 4 for the optical fiber 12 connected to the device 2.

Also in the method of superimposing with the information communication signal (Japanese Patent Laid-Open No. 6232842), it is not assumed that visible light is input in the opposite direction to the information communication wavelength, and even excitation light is visible. There is no proposal to superimpose it in the same direction as the light. In any case, the conventional purpose of using visible light was to improve the operational efficiency of the optical fiber communication system, whereas the purpose of using the communication module 1 of the present invention is to improve safety and energy efficiency.

<Second Embodiment> Similar to the first embodiment, the transmission side module 21 and the reception side module 22 which are communication modules may be arranged outside the transmission device 20 and the transmission device 2, respectively. Alternatively, it may be included (may be provided) in each of the transmission device 20 and the transmission device 2. As described above, in the second embodiment, the communication module is composed of the transmission side module 21 and the reception side module 22.

The transmission side module 21 is provided with an input port 40 for inputting the information communication light from the transmission device 20 at one end and an output port 43 for emitting the information communication light to the reception side module 26 at the other end. It is provided in the transmission device (transmission side) 20, and includes a fiber bend detection light source 23, a data generator 25, and a data modulator 24 inside. Here, the fiber bend detection light source 23 uses, for example, a long wavelength band, and has a wavelength in the U band band (1625/1675 nm) defined by so-called ITU.
However, the fiber bending detection light source 23 is
It does not have to be the wavelength of the U band band (1625/1675 nm) specified in (ITU-T draft Supplement Sup.dsn).

In the present invention, the wavelength of the fiber bending detection light generated by the fiber bending detection light source 23 is set to the long wavelength band because the light in the long wavelength band is sensitive to the bending of the fiber, and the Raman excitation is performed. When light (C band (1530-1565 nm) is used for light for information communication (information communication light), a loss occurs with bending at a local rate larger than 1450 nm. It is also because the L band (1565-1625 nm) can be used for information communication, but is defined for maintenance in the U band.

That is, in the receiving side module 26, the pumping light source 28 for pumping distribution amplification is shut off based on the power monitor of the U band. The input port 40 is simply connected to the optical coupler 22, and the output port 41 is connected to the other end.
Are connected, and the fiber bending detection light source 23 is connected to the input port 40 side.

Data generator 2 in the transmitting module 21
5 is a relatively slow PRBS (Pseudo Random Binary Sequen)
ce) pattern generator, but a fixed pattern may also be used,
A sine wave with a specific frequency may be used, or a direct current (D
It may be C). In the case of direct current, for example, "1" is continuously generated, and there is no problem if the fiber bend detection light receiver 31 receives "1", and if "0" is received (that is, if nothing can be received). The data analyzer 32 determines that there is a problem. Here, the reason why the PRBS pattern is generated at a low speed is that the reception sensitivity is high and the SN limitation is less likely to occur.

For example, in 10 Mbit / s transmission, 10
Compared to Gbit / S, the SN of 1000 times (30dB) can be relaxed. Therefore, even if the Raman excitation light is not incident, the data generated by the data generator 25 is
There is a possibility that it can be received at 6. The transmission / reception confirmation of the data generated by the data generator 25 is used for restoration after the excitation light is blocked.

Here, the fiber bending detection light source 23 emits the fiber bending detection light modulated by the PRBS pattern (electrical signal data) generated by the data generator 25 to the optical coupler 22 under the control of the data modulator 24. To do.
As a result, the optical coupler 22 superimposes the information communication light and the fiber bending detection light on each other and outputs the superimposed light to the receiving module.

The receiving side module 26 is provided with an input port 42 for receiving the information communication light and the fiber bending detection light from the transmitting side module 21 at one end, and an output port for emitting the information communication light to the transmission device 2 at the other end. 43 is provided,
Similar to the first embodiment, a pumping light source 28 for pumping distribution amplification that emits pumping light that amplifies information communication light, a visible light source 30 that emits visible light, and an optical coupler 2 that performs optical coupling.
7. It includes the excitation light source cutoff / restoration unit 29, and further includes the fiber bend detection receiver 31 and the data analyzer 32. Here, the fiber bend detection receiver 31 and the data analyzer 32 are connected to the excitation light source blocking / restoring means 29 by a control line. The input port 42 is simply connected to the optical coupler 27, the output port 43 is connected to the other end, and the excitation light source 28 and the fiber bend detection light receiver 31 are connected to the output port 43 side.

The second embodiment is characterized in that it does not have an external control interface as in the first embodiment. The excitation light emitted from the excitation light source 28 and the visible light emitted from the visible light source 30 are superposed by the optical coupler 27 and emitted from the input port 42 to the transmission side module 21.

Next, the cutoff / restoration operation of the communication module of FIG. 2 will be described with reference to FIG. FIG. 3 is a flow chart for explaining a disconnection / restoration process when the connector is attached / detached, the fiber is cut or the fiber is bent. Optical power in the long wavelength band is lost due to connector attachment / detachment, fiber breakage, and fiber bending.

Then, in step S1, the fiber-bending detection light receiver 31 detects whether or not the fiber-bending detection light incident from the optical coupler 27 has a numerical value of a predetermined intensity or more. Here, if the fiber bending detection light is smaller than the predetermined intensity, the fiber bending detection light receiver 31 proceeds to step S2. On the other hand, if the fiber bending detection light exceeds the predetermined intensity, the fiber bending detection light is detected. It is determined that there is no fiber break, and the process proceeds to step S1.

Next, in step S2, the excitation light source cutoff / restoration unit 29 causes the excitation light source 28 to disconnect the optical coupler 2.
The excitation light is blocked from being emitted to the light source 7, and is prevented from being propagated from the excitation light source 28 into the fiber. Especially when the fiber is bent, even if the high output power has a bend radius that does not suffer much loss, the light in the long wavelength band suffers loss,
It is important to shut off before falling into danger.

Here, if the cutoff function is faulty, as in the first embodiment, the visible light is emitted from the visible light source 30 to the optical coupler 27, and the visible light is superimposed on the excitation light. By this, the maintenance person can recognize that the light of high output power is leaking by recognizing the visible light emitted from the connector that connects the optical fiber to each module in the state of the fiber cut, and the generation of heat, etc. It is possible to prevent wasteful consumption of energy.

Next, in step S3, when the connector and the optical fiber are returned to the normal state, the pumping light is not propagated in the fiber in this state, so the wavelength light for information communication is transmitted to the transmission device (reception side) 2. It may not have arrived. Next, in step S3, the receiving module 2
When the connector and the optical fiber return to the normal state, the fiber bending detection light is incident on 6.

Then, the optical receiver 31 for detecting the fiber bend
Inputs the fiber bending detection light through the optical coupler 27, converts the fiber bending detection light into an electric signal,
A PRBS pattern is extracted from this electrical signal, and this PRBS pattern (electrical signal data) is output to the data analyzer 32. As a result, the data analyzer 32 receives the PRBS pattern in the fiber bending long wavelength band and at a low speed.

Then, the data analyzer 32 is input.
If the PRBS pattern is analyzed and there is no error in the analysis result (if normal), it is detected that the connector and the optical fiber are normal, and the process proceeds to step S4. Next, in step S4, the excitation light source cutoff / restoration unit 29 activates the excitation light source 28 to turn on the optical coupler 2.
The excitation light is emitted to 7.

In step S5, since the optical fiber communication system emits the pumping light, the wavelength for information communication is subjected to Raman amplification and settles in a normal state, and whether or not to continue the process, that is, the system. Is detected. The optical fiber communication system returns the processing to step S1 when continuing the data transmission processing, and ends the processing when stopping the data transmission processing. As described above, in the communication module of the present invention, it is an important point that the PRBS pattern generation timing of the data generator 25 is slowed to improve the reception sensitivity in the data analyzer 32.

<Third Embodiment> FIG. 4 is a block diagram showing an example of the arrangement of an optical communication module according to the third embodiment of the present invention. In this figure, the transmitter module 50
May be provided outside the transmission device 20 on the transmission side, or may be included (arranged) in the transmission device 20. Similarly, the reception-side module 51 may be provided outside the transmission device 2 on the transmission side or may be included (arranged) in the transmission device 2.

The transmitting side module 50 and the receiving side module 51 have the same structure as shown in FIG. 4, and the functions of both the transmitting side module 21 and the receiving side module 26 in the second embodiment are integrated. The same reference numerals as those in the second embodiment are attached to the configurations that have the same configuration and perform the same functions and operations. In addition, in the operation of the third embodiment, the same operation as that of the transmitting side module 21 and the receiving side module 26 in the second embodiment is performed.
Opposing transmission side module 50 and reception side module 51
It will be done between and. In general, Raman amplification is
In the receiving-side module 26, the pumping light is often injected from the receiving side (backward pump system) so that the pumping light source 28 emits the pumping light.

However, in order to improve the SN of the information communication light, a so-called forward pump system in which pumping light is injected from the transmitting side may be used together. The third embodiment is directed to a configuration related to bidirectional pumping that uses both forward and backward pumping methods in which pumping light is injected into the transmission line from both the transmitting side and the receiving side.

As can be seen from FIG. 3, the transmission side module 5
0, the fiber bend detection light source 31 is provided on the transmission side transmission device 20 side (input port 40 side), and similarly, in the reception side module 51, the fiber bend detection light source 31 is the reception side transmission device 2 side. (Output port 43 '
Side). In the transmission side module 50, the excitation light source 28 is connected to the transmission line side (the output port 43
Side), and similarly, in the reception side module 51, the excitation light source 28 has the transmission line side (input port 40 'side).
It is provided in. Therefore, the pumping light from the pumping light source 28 and the fiber bending detection light from the fiber bending detection light source 31 propagate bidirectionally in one transmission path (optical fiber).

There is no problem for the pumping light by terminating it with an isolator or the like. However, the fiber bending detection light needs to be received by the fiber bending detection light receiver 31 because it is necessary to detect the degree of bending of the optical fiber. Here, the fiber bending detection light sources 2 of the transmitting side module 50 and the receiving side module 51, respectively.
If the same wavelength (carrier) is used in 3, the Rayleigh scattering may decrease the reception sensitivity (detection sensitivity) of the other fiber bending detection light by one fiber bending detection light.

Therefore, in the third embodiment, in order not to reduce the receiving sensitivity of the fiber bending detection light, the fiber bending detection light sources 23 of the transmitting side module 50 and the receiving side module 51 respectively bend the fibers of different wavelengths. An optical bandpass filter is provided in front of the fiber bending detection light receiver 31 using the detection light (in the U band) to receive light of a required wavelength, that is, each of the fiber bending detection light receivers 31. Allow only light of the correct wavelength to pass.

When the same wavelength is used, the fixed pattern of the data is set to a sine wave having a different frequency, and an electrical bandpass filter is provided in the subsequent stage of the optical receiver for fiber bend detection 31 to detect the optical signal for fiber bend detection. May be converted into an electric signal by the fiber bending detection light receiver 31, and then only the electric signal of a desired frequency may be passed from the electric signal by the band pass filter. Other operations are similar to those of the second embodiment, and detailed description thereof will be omitted.

Although one embodiment of the present invention has been described in detail above with reference to the drawings, the specific structure is not limited to this embodiment, and design changes and the like within the scope not departing from the gist of the present invention. Even so, it is included in the present invention.

[0068]

According to the present invention, even when the disconnection function fails when the connector is attached or detached or the fiber is broken, the maintenance personnel can recognize the light leakage by the visible light, and the bending of the optical fiber can be prevented. Even so, it is possible to realize a cutoff function sensitive to fiber bending, and it is also possible to provide a cutoff recovery function for an optical fiber communication system. As a result, according to the present invention, it is possible to maintain the safety of the high-power optical fiber communication system and perform the operation while suppressing wasteful energy consumption.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration example of a communication module according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration example of a communication module according to a second embodiment of the present invention.

FIG. 3 is a flowchart for explaining an operation example of a communication module according to a second embodiment of the present invention.

FIG. 4 is a flowchart for explaining an operation example of a communication module according to a third embodiment of the present invention.

[Explanation of symbols]

1 Communication module 2,20 Electric transmission device 3,40,42,40 'Input port 4,41,43,43 'Output port 5,22,27 Optical coupler 6,28 Excitation light source 7,30 visible light source 8 Excitation light source blocker 9 Interruption control interface 10 control lines 11,12 optical fiber 21,50 transmitter module 23 Fiber bend detection light source 24 Data modulator 25 data generator 26,51 Receiver module 29 Excitation light source cutoff / recovery unit 31 Fiber bend detector 32 data analyzer

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Yuu Miyamoto             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation F term (reference) 5F072 AB07 AB13 AK06 HH02 HH09                       JJ05 JJ11 PP07 QQ07 RR01                       YY17                 5K002 AA01 AA03 AA07 BA04 BA05                       CA13 EA06 FA01 GA03

Claims (20)

[Claims] 1. An optical communication module comprising a fiber input port and a fiber output port, wherein an optical signal for information communication is input from the fiber input port and used for optical fiber communication output from the fiber output port. In the optical communication module, an optical directional coupler, a distributed amplification pumping light source, and a visible light source, the directional coupler is connected to the fiber input port at one end, the other end at the Fiber output port is connected,
An optical communication module, wherein the pumping light source for amplifying pumped distribution and the visible light source are connected to an output port side of the directional coupler, and pumping light and visible light are output from the fiber input port. 2. A means for cutting off the pumping light source for amplifying the pumping distribution, and a control signal interface for controlling the pumping light blocking means.
The optical communication module described in. 3. An optical communication module comprising a fiber input port and a fiber output port, wherein an optical signal for information communication is input from the fiber input port and used for optical fiber communication output from the fiber output port. In the optical communication module, the optical communication module is composed of a transmitting side module and a receiving side module, the transmitting side module comprises an optical directional coupler, and a fiber bend detection light source, the optical directional coupler , The fiber input port is connected to one end, the fiber output port is connected to the other end, the fiber bend detection light source is connected to the fiber input port side of the directional coupler, the receiving module, the optical directional Coupler, pumping light source for pumping distribution amplification, optical receiver for detecting fiber bend, and pumping light source for pumping distribution amplification A cutoff means, the directional coupler is connected to the fiber input port at one end, the fiber output port is connected to the other end, the pumping light source for pumping distribution amplification and the optical receiver for detecting fiber bending. Is connected to the fiber output port side of the directional coupler, and the fiber bend detection optical receiver and the pumping distribution amplification pumping light source blocking means are connected by a control line. module. 4. The transmission side module comprises a data generator and means for modulating the fiber bend detection light source with the data, and the reception side module outputs from the fiber bend detection optical receiver. Means for analyzing electric signal data, means for controlling and blocking the excitation light source blocking means for excitation distribution amplification based on the analysis result, and excitation for amplification distribution amplification based on the normality of the analysis result The optical communication module according to claim 3, further comprising means for controlling the light source cutoff means to restore the cutoff. 5. The optical communication module according to claim 3, wherein the reception side module includes a visible light source that emits visible light to the optical directional coupler. 6. A module for optical communication, comprising a fiber input port and a fiber output port, wherein an optical signal for information communication is input from the fiber input port and is output from the fiber output port. In the optical communication module, the module for optical communication is composed of a module on the transmitting side and a module on the receiving side, and the module for transmitting is a first optical directional coupler, a second optical directional coupler, and a light source for fiber bend detection. And a pumping light source for pumping distribution amplification,
An optical receiver for detecting a fiber bend and means for cutting off the pumping light source for amplifying the pumping distribution are provided, and the fiber bend detecting light source is connected to the fiber input port side of the first optical directional coupler, and the other end is provided. Is connected to the second optical coupler, the pumping light source for pumping distribution amplification is connected to the fiber output port side of the second directional coupler, and the receiving module is a third optical directional coupler. A fourth optical directional coupler, a fiber bending detection light source, a distribution amplification pumping light source, a fiber bending detection light receiver, and means for cutting off the pumping distribution amplification pumping light source. A fiber bend detection light source is connected to the fiber output port side of the third optical directional coupler, the fourth optical coupler is connected to the other end, and the pumping light source for pumping distribution amplification is the fourth light source. Of directional coupler An optical communication module, which is connected to a fiber input port side. 7. The transmission side module and the reception side module each include a data generator and means for modulating the fiber bend detection light source with the data, and in the transmission side module and the reception side module, The optical receiver for fiber bend detection comprises means for analyzing electric signal data obtained by photoelectrically converting the light output from the modules facing each other, and based on the analysis result, the excitation light source blocking means for each pumping distribution amplification 7. The optical communication according to claim 6, further comprising: means for controlling and shutting off, and means for controlling and shutting off the pumping light source for pumping distribution amplification based on the normality of the analysis result to restore the interruption. Module. 8. The module according to claim 6, wherein the receiving side module and the transmitting side module each include a visible light source that emits visible light to the optical directional coupler. Optical communication module. 9. A transmission for optical communication used for optical fiber communication, comprising a fiber input port and a fiber output port, wherein an optical signal for information communication is input from the fiber input port and output from the fiber output port. In the side module, an optical directional coupler and a fiber bending detection light source are provided, and the optical directional coupler is connected to the fiber input port at one end and the fiber output port at the other end, and An optical communication transmitting side module, wherein a fiber bend detecting light source is connected to an input port side of the directional coupler. 10. The optical communication according to claim 9, further comprising a data generator for generating predetermined data, and means for modulating light emitted from the fiber bend detection light source with the data. Sender module. 11. An optical communication transmission used for optical fiber communication, comprising a fiber input port and a fiber output port, wherein an information communication optical signal is input from the fiber input port and output from the fiber output port. In the side module, a first optical directional coupler, a second optical directional coupler, a fiber bending detection light source, a distributed amplification pumping light source, a fiber bending detection optical receiver, and the distributed amplification. Means for shutting off a pumping light source for the first optical directional coupler, wherein the first optical directional coupler has the fiber input port at one end and the second optical input port at the other end.
The optical directional coupler is connected, and the distributed amplification pumping light source is connected to the fiber output port side of the second optical coupler. 12. A data generator for generating predetermined data, and means for modulating the light emitted from the fiber bend detection light source by the data, and output from the fiber bend detection optical receiver. Means for analyzing electrical signal data, means for controlling and shutting off the pumping light source blocking means for pumping distribution amplification based on the output of the receiver, and for pumping distribution amplification based on the normality of the analysis data The optical communication transmission side module according to claim 11, further comprising means for controlling the excitation light source cutoff means to restore the interruption. 13. A transmission side module for optical communication according to claim 11, wherein the transmission line has a visible light source that emits visible light via the second optical directional coupler. . 14. An optical communication receiver for use in optical fiber communication, comprising a fiber input port and a fiber output port, wherein an information communication optical signal is input from the fiber input port and output from the fiber output port. In the side module, an optical directional coupler, a fiber bending detection light source, a distribution amplification pumping light source, a fiber bending detection light receiver, and means for cutting off the distribution amplification pumping light source, A directional coupler is connected to the fiber input port at one end, and the fiber output port is connected to the other end, and the pump light source for pumping distribution amplification and the optical receiver for fiber bend detection are the directional coupler. Is connected to the fiber output port side, and the fiber bend detection optical receiver and the excitation light source blocking means are connected by a control line. The receiving-side module for optical communications 15. A means for analyzing electric signal data output from the fiber bend detecting optical receiver, and means for controlling and interrupting the excitation light source interrupting means based on the output of the receiver, 15. The optical communication receiving side module according to claim 14, further comprising means for controlling the excitation light source interruption means based on the normality of the analysis data to restore interruption. 16. The receiving module for optical communication according to claim 14 or 15, further comprising a visible light source that makes visible light incident on the optical directional coupler. 17. A receiver for optical communication, comprising a fiber input port and a fiber output port, wherein an optical signal for information communication is input from the fiber input port and is output from the fiber output port. In the side module, a first optical directional coupler, a second optical directional coupler, a fiber bending detection light source, a distributed amplification pumping light source, a fiber bending detection optical receiver, and the distributed amplification. Means for shutting off the pumping light source for said first optical directional coupler, said first optical directional coupler having said fiber output port at one end and said second optical output port at the other end.
The optical directional coupler is connected, and the distributed amplification pumping light source is connected to the fiber input port side of the second optical coupler. 18. A data generator for generating predetermined data, and means for modulating the light emitted from the fiber bend detection light source with the data, and output from the fiber bend detection optical receiver. Means for analyzing electrical signal data, means for controlling and shutting off the pumping light source blocking means for pumping distribution amplification based on the output of the receiver, and for pumping distribution amplification based on the normality of the analysis data 18. The receiving module for optical communication according to claim 17, further comprising means for controlling the pumping light source blocking means to restore blocking. 19. The optical communication receiving side module according to claim 17, wherein the transmission line has a visible light source for emitting visible light through the second optical directional coupler. . 20. A transmission side module and a reception side module comprising a fiber input port and a fiber output port, wherein an optical signal for information communication is input from the fiber input port and output from the fiber output port. In the method for recovering from interruption of an optical fiber communication system, a step of generating predetermined data by a data generator, a step of modulating light emitted from a light source for detecting a fiber bend with the data, and a step of transmitting the modulated light. A step of emitting from the trust module, a step of entering the light into the receiving module, and a step of analyzing electric signal data output from the fiber bend detecting optical receiver based on the incident light, Based on the analysis results, the process of controlling and blocking the excitation blocking means for excitation distribution amplification, and the normalization of the analysis results Blocking recovery method of an optical fiber communication system characterized by having a process to recover blocked by controlling the electromotive distribution amplification pumping blocking means.