JPH0715055A - Optical signal direct amplifier - Google Patents

Abstract

PURPOSE:To realize an optical signal direct amplifier capable of detecting the coming-off of an optical connector and automatically restarting the system after recovery. CONSTITUTION:The optical signal amplified by an erbium-doped fiber 14 is delivered to an optical output connector 17 through a first and a second optical directional couplers. When the connector is not detached, the detection output of a first photodetector 18 is large as compared with that of a second photodetector 23 for detecting reflection return light. An automatic power control circuit 19 controls a laser driving circuit 21, and controls the output of a pumping light source 13 to be in a normal range. When the connector comes off, the output of the second photodetector 23 increases, and the level of signal after amplified by a level adjusting circuit 61 increases. As the result, the automatic power control circuit 19 gets the pumping light down to a safe level. When an obstacle is restored, an optical signal of initial level is delivered to the optical output connector 17.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical signal direct amplifier for directly amplifying an optical signal as it is, and more specifically, to stop or reduce the output power when the optical connector on the output side is disconnected. The present invention relates to an optical signal direct amplifier.

[0002]

2. Description of the Related Art A high output optical signal is output from an optical transmitter. It is dangerous for such a high-power optical signal to be seen by a person performing maintenance or management work. For this reason, there has been conventionally known an optical amplifying device which detects an accident that an output connector of a high output optical amplifier is disconnected by an increase in the reflection amount of an optical signal and automatically stops or reduces the output power.

FIG. 2 shows a circuit configuration of such a conventional optical amplifier device. An optical signal input from the input optical connector 11 of this device is input to a wavelength division multiplexer (WDM) 12. The pumping light from the pumping light source 13 is also input to the wavelength division multiplexing coupler 12, and the two are combined to form an erbium-doped fiber (Erbium Doped Fiber).
Fiber) 14 is input.

The erbium-doped fiber 14 is an amplifier that directly amplifies the input light, and the amplified optical signal passes through a first optical directional coupler 15 and a second optical directional coupler 16 and an optical output connector 17 is provided. Is output to. here,
The first optical directional coupler 15 branches a part of the input optical signal and inputs it into the first light receiving element 18. The output of the first light receiving element 18 is an automatic power control (APC;
Control) circuit 19 is input. The output of the automatic power control circuit 19 is input to the laser drive circuit 21, which causes the laser drive circuit 21 to apply a current to the excitation light source 13 so that the output of the first light receiving element 18 becomes constant. Will be adjusted.

On the other hand, the second optical directional coupler 16 splits the reflected return light and inputs it into the second light receiving element 23. In general, a part of the optical signal output from the optical output connector 17 is reflected from the end face of the optical output connector 17 or the transmission path and returns to the amplifier side again. If the optical output connector 17 comes off, the amount of reflected return light increases. The second optical directional coupler 16 will detect this reflected return light. The output of the second optical directional coupler 16 is input to the determination circuit 24, where the output optical connector disconnection is determined. When the determination circuit 24 determines that the output optical connector is disconnected, a signal for stopping the current application to the laser drive circuit 21 is generated. Based on this, the laser drive circuit 21 changes the current applied to the excitation light source 13 to “0” amperes, and stops the output of the excitation light.

On the other hand, FIG.
10 shows an optical output control circuit of the optical connector connection type device disclosed in Japanese Patent Laid-Open No. In this circuit, the output connector 32 to which the optical fiber 31 is connected is the receptacle 33.
The output of the laser diode 36 in the automatic output control circuit 35 is detected by the optical output control unit 34 when it is out of the range.

That is, in the automatic output control circuit 35 of this optical output control circuit, the input signal 37 is added to the output of the bias circuit 39 by the adder 38 and given to the laser diode 36,
It is designed to control the light emission, and the photodiode 41
Then, a part of it is detected and amplified by the amplifier 42, and the reference voltage 4
A feedback loop is configured so that 3 is input to the other end of the differential amplifier 44.

On the other hand, a sensor light emitter 46 and a sensor light receiver 47 are arranged in the vicinity of the output connector 32, and when the output connector 32 is disengaged from the receptacle 33, the light reflected by the outer periphery of the output connector 32 is detected by the sensor light receiver. The amount of light incident on 47 is reduced. The output of the sensor light receiver 47 is amplified by an amplifier 48, and a comparator 49
It is input to one input terminal and compared with the threshold voltage 51 applied to the other input terminal. Then, when the amount of light incident on the sensor light receiver 47 decreases the threshold value, it is determined that the output connector 32 is disconnected, and the output level of the comparator 49 is changed to change the potential on the reference voltage 43 side to change the potential of the laser diode 36. It is designed to reduce the output.

In Japanese Utility Model Application No. 62-20003 (Japanese Utility Model Application Laid-Open No. 63-127655), a treatment area exists by irradiating a light beam in the vicinity of the laser light irradiation area and detecting the reflected light. There is disclosed a technique in which it is determined whether or not a treatment site does not exist and irradiation with laser light is not performed.

Japanese Patent Publication No. 58-14218 discloses that
Disclosed is a probe detachment detection device which generates an alarm when a probe that comes into contact with a human body is detached. In this probe detachment detection device, a light receiving means is arranged on the human body contact surface side of the probe, and when the probe detaches, ambient light is detected to make the determination, and an alarm is generated. .

[0011]

By the way, as described above, when the connector disconnection occurs on the output side of the optical signal direct amplifier, the reflection at the end face of the optical output connector increases, and the conventional optical signal shown in FIG. In the direct amplifier, the determination circuit 24 detects the increase of the reflected return light laser and stops the output of the pumping light from the pumping light source 13. After this, the reflected return light disappears, so that the connector is apparently mounted normally. Then, the alarm warning that the connector is disconnected will be canceled.

Therefore, in the conventional optical signal direct amplifier shown in FIG. 2, once the connector disconnection is detected, the drive of the pumping light source 13 is stopped and this state is maintained. As a result, the warning associated with the driving stop of the excitation light source 13 is released, or the excitation light source 1 is released with the connector disconnected.
3 is prevented from being restarted. However, in this optical signal direct amplifier shown in FIG. 2, since the pumping light source itself is stopped, the reflected return light cannot be detected, and the connector is normally operated after the alarm is issued. Even if it is attached, this cannot be detected by the circuit.
Therefore, when recovery is performed after the alarm is issued, it is necessary to manually release the alarm and restart the optical signal direct amplifier.

Further, in the conventional optical output control circuit shown in FIG. 3, the output of the laser diode 36 is controlled by utilizing the reflected light on the outer periphery of the output connector 32, so that some kind of reflection object is detected by the sensor light emitter 46. If it is brought closer to the sensor light receiver 47 or the sensor light receiver 47, the output level of the laser diode 36 will erroneously return to a normal value, which is dangerous.

Therefore, an object of the present invention is to basically use the conventional optical signal direct amplifier as shown in FIG. 2 to detect the disconnection of the connector and to automatically restart after the recovery. To provide.

[0015]

According to a first aspect of the present invention, there is provided a rare earth-doped fiber as an optical signal amplifying medium,
A pumping light source that sends pumping light to this rare earth-doped fiber, a laser drive circuit that drives this pumping light source, a wavelength division multiplexer that combines the optical signal input to the rare earth-doped fiber and the pumping light, and a rare earth-doped fiber First branching part of the optical signal sent to the optical connector on the output side
Optical branching device, a first light receiving element for detecting an optical signal branched by the first optical branching device, a second light receiving element for detecting reflected return light from the output side optical connector, and these first light receiving element And an automatic power control circuit for controlling the laser drive circuit so that the operation result of the second light receiving element is added at a predetermined ratio and the operation result of the second light receiving element becomes a predetermined value. Prepare for the amplifier.

That is, according to the first aspect of the present invention, a part of the optical signal output from the rare earth-doped fiber and the reflected return light from the optical connector on the output side are calculated at a predetermined ratio, and this is calculated by the laser drive circuit. It is supposed to be used as an input signal of an automatic power control circuit for controlling. When the connector is disconnected, the optical signal output from the rare earth-doped fiber is reduced by increasing the input signal of the automatic power control circuit due to the increase of reflected return light, and when the connector is properly attached, When the input signal of the automatic power control circuit falls to the normal range, automatic restart after restoration is possible.

According to a second aspect of the invention, an erbium-doped fiber as an optical signal amplifying medium, a pumping light source for sending pumping light to the erbium-doped fiber, a laser drive circuit for driving the pumping light source, and an erbium-doped fiber. A wavelength division multiplexing coupler that combines an optical signal input to the fiber and the pumping light; a first optical branching device that branches a part of the optical signal sent from the erbium-doped fiber to the output side optical connector; The first light receiving element for detecting the optical signal branched by the first optical branching device, the second light receiving element for detecting the reflected return light from the output side optical connector, and the output of the second light receiving element are predetermined. Level adjusting circuit that amplifies the output of the first light receiving element and the output of the level adjusting circuit, and that the output of the adder has a predetermined value. An automatic power control circuit is provided in the optical signal direct amplifier for controlling THE drive circuit.

That is, according to the second aspect of the present invention, the reflected return light from the optical connector on the output side is received by the second light receiving element, its output is amplified to a predetermined level by the level adjusting circuit, and after this amplification. The signal level and the output after photoelectric conversion of a part of the optical signal output from the erbium-doped fiber are added by an adder. The output of this adder is used as an input signal of an automatic power control circuit that controls the laser drive circuit. When the connector is disconnected, the optical signal output from the erbium-doped fiber is reduced by increasing the input signal of the automatic power control circuit due to the increase of reflected return light, and when the connector is properly attached, When the input signal of the automatic power control circuit falls to the normal range, automatic restart after restoration is possible.

According to a third aspect of the present invention, in the optical signal direct amplifier of the second aspect, the reflected return light from the optical connector side is branched between the optical connector on the output side and the erbium-doped fiber. Then, the second first optical branching device for supplying the second light receiving element is arranged.

[0020]

EXAMPLES The present invention will be described in detail below with reference to examples.

FIG. 1 shows the configuration of an optical signal direct amplifier according to an embodiment of the present invention. The same parts as those in FIG. 2 are designated by the same reference numerals. In the optical signal direct amplifier of the present embodiment, the output signal output from the second light receiving element 23 is input to the level adjusting circuit 61, the level thereof is adjusted, and then input to the adder 62. Adder 6
The output signal of the first light receiving element 18 is also input to 2, and the two are added. The output of the adder 62 is input to the automatic power control circuit 19. The control of the laser drive circuit 21 by this is the same as that of the optical signal direct amplifier shown in FIG.

The operation of the optical signal direct amplifier having such a configuration will be described. The optical signal input from the input optical connector 11 is combined with the pumping light output from the pumping light source 13 by the wavelength division multiplexing coupler 12, and the erbium-doped fiber 14
After being amplified by, the light is output from the optical output connector 17.
A part of the optical signal amplified by the erbium-doped fiber 14 is branched by the first optical directional coupler 15 and received by the first light receiving element 18. In addition, the reflected return light reflected by the optical output connector 17 is the second optical directional coupler 1.
It passes through 6 and enters the second light receiving element 23.

First, the case where the optical output connector 17 is properly mounted will be described. In this case, the output of the second light receiving element 23 is 40d greater than the output of the first light receiving element 18.
It is also lower than B. Therefore, the output of the adder 62 becomes equal to the output of the first light receiving element 18. Automatic power control circuit 1
9 controls the laser drive circuit 21 so that the output of the first light receiving element 18 is always constant, and in this situation, the output light level of this optical signal direct amplifier is kept constant. Become.

Next, the case where the optical output connector 17 is disconnected will be described. When disconnection of the optical output connector occurs, the reflected return optical power input to the second light receiving element 23 increases several hundred times as compared with the case where the connector is properly mounted. As a result, the output of the second light receiving element 23 also increases several hundred times.
This output is amplified by the level adjusting circuit 61 and added by the adder 62.
Entered in. The output of the adder 62 is the first light receiving element 18
And the output of the level adjusting circuit 61. As a result, the automatic power control circuit 19 apparently determines that the output light level of the erbium-doped fiber 14 has increased, and controls the laser drive circuit 21 to reduce the output light level of the pumping light source 13.

By the way, the amplification degree of the level adjusting circuit 61 is set so that the output level of the erbium-doped fiber 14 is weakened so that the human body is not affected when it is assumed that total reflection occurs at the optical output connector 17. Therefore, even when the optical output connector is disconnected, the optical signal is output from the erbium-doped fiber 14 at a level that does not affect the human body, and the reflected return light due to the optical output connector disconnection does not become zero. Therefore, while the optical output connector 17 is disconnected, it is possible to always detect the optical output connector disconnection.

When the optical output connector 17 is mounted again after the disconnection of the optical output connector, the reflected return light level is greatly reduced as before. As a result, the adder 62
Again becomes approximately equal to the output level of the first light receiving element 18. As a result, the automatic power control circuit 19 restores the output light level of the pumping light source 13 and the output light level of the erbium-doped fiber 14 returns to the normal output level.

In the embodiment, the erbium-doped fiber is used for the optical signal direct amplifier, but other rare earth-doped fiber can be used. Further, in the embodiment, the output of the second light receiving element 23 is set to the level adjusting circuit 6
Although the output of the first light receiving element 18 is added to the output of the first light receiving element 18 after adjustment by 1, the arithmetic circuit for adding the outputs of both the light receiving elements 18 and 23 at a predetermined ratio is provided, and the level adjusting circuit 61 is omitted. It is also possible to do so.

[0028]

As described above, claims 1 to 3 are as described above.
According to the invention described above, the level of the optical signal output from a rare earth-doped fiber such as an erbium-doped fiber is not reduced to zero even when the optical output connector is disconnected, so that a special holding circuit is required. It is possible to maintain the connector detached state without performing. Moreover, when the connector disconnection is restored, the output level of the optical signal automatically returns to the normal state, so that the efficiency of maintenance and the like can be improved. Further, according to the present invention, an optical signal direct amplifier that can completely cope with connector disconnection can be formed with almost no change to the existing optical signal direct amplifier, so that an economical optical communication system can be configured. .

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of an optical signal direct amplifier according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a circuit configuration of a conventionally proposed optical amplifier.

FIG. 3 is a block diagram showing an optical output control circuit of a conventionally proposed optical connector connection type device.

[Explanation of symbols]

11 Input Optical Connector 12 Wavelength Division Multiplexer 13 Excitation Light Source 14 Erbium Doped Fiber (Rare Earth Doped Fiber) 15 First Optical Directional Coupler 16 Second Optical Directional Coupler 17 Optical Output Connector 18 First Photosensitive Element 19 Automatic power control circuit 21 Laser drive circuit 23 Second light receiving element 61 Level adjusting circuit 62 Adder

Claims (3)

[Claims] 1. A rare-earth-doped fiber as an amplification medium for an optical signal, a pumping light source for sending pumping light to the rare-earth-doped fiber, a laser drive circuit for driving the pumping light source, and light input to the rare-earth-doped fiber. A wavelength division multiplexing coupler for multiplexing a signal and the pumping light, a first optical branching device for branching a part of an optical signal sent from the rare earth-doped fiber to an optical connector on the output side, and a first optical branching device. A first light receiving element for detecting the optical signal branched by the optical device, a second light receiving element for detecting the reflected return light from the output side optical connector, and outputs of the first and second light receiving elements are predetermined. And an automatic power control circuit for controlling the laser drive circuit so that the calculation result of the calculation means has a predetermined value. Vessel. 2. An erbium-doped fiber as an optical signal amplifying medium, a pumping light source for sending pumping light to the erbium-doped fiber, a laser drive circuit for driving the pumping light source, and light for inputting to the erbium-doped fiber. A wavelength division multiplexing coupler for multiplexing a signal and the pumping light, a first optical branching device for branching a part of an optical signal sent from the erbium-doped fiber to an optical connector on the output side, and a first optical branching device. A first light receiving element for detecting an optical signal branched by the optical device, a second light receiving element for detecting reflected return light from the output side optical connector, and an output of the second light receiving element at a predetermined level. A level adjusting circuit for amplifying, an adder for adding the output of the first light receiving element and the output of the level adjusting circuit, and the laser for adjusting the output of the adder to a predetermined value. And an automatic power control circuit for controlling the drive circuit. 3. A second first optical branch between the optical connector on the output side and the erbium-doped fiber, which branches the reflected return light from the optical connector side and supplies it to the second light receiving element. The optical signal direct amplifier according to claim 2, wherein the optical amplifier is arranged.