JPH07190887A - Automatic optical-output drop circuit of optical amplifier - Google Patents

Abstract

PURPOSE:To provide the automatic optical-output drop circuit, of an optical amplifier, whose operability and maintainability are good and which can be made compact. CONSTITUTION:The automatic optical-output drop circuit is constituted of a comparator 5 in which a part of the optical output of an optical fiber amplifier is monitored by an optical-output monitoring circuit 3, in which an optical- output monitoring signal and a part of reflected light from an optical-output connector are monitored by a reflected-light monitoring circuit 4 and which always compares a reflected-light monitoring signal, of a switch 63 which is operated on the basis of the compared output of the comparator and of a bias circuit 7 in which the amplified output of the optical fiber amplifier corresponding to a first or second reference voltage is obtained by the operation of the switch.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical output automatic lowering circuit of an optical amplifier, which has a function of protecting a human eye and the like from an optical output output from an optical fiber amplifier constituting an optical communication system. The present invention relates to a circuit for automatically lowering the optical output of an optical amplifier when the output end of the optical amplifier is open.

[0002]

2. Description of the Related Art Generally, an optical amplifier is a semiconductor optical amplifier,
There are three optical amplifiers, a rare earth doped fiber optical amplifier and a Raman optical amplifier. Similar to the laser diode, the semiconductor optical amplifier utilizes the gain mechanism of the semiconductor active layer by current injection, operates the device below the oscillation threshold value, and obtains the optical amplification effect for the injection light from the outside. A rare-earth-doped fiber optical amplifier uses an optical fiber in which a core element of the fiber is doped with an earth element such as Ed ³⁻ or Er ³⁺ as an amplifying medium. In particular, an Ed ³⁺ doped optical fiber has a wavelength of 1.55 μm Has a laser transition frequency at
Since optical amplification in that wavelength range is possible, application to optical communication systems can be expected. Further, in the Raman optical amplifier, an amplification effect is obtained by utilizing the stimulated Raman scattering phenomenon, which is a non-linear optical effect, in the process of converting the optical power from the pump light to the signal light. As an application form of these optical amplifiers to an optical communication system, they are applied to an optical amplification repeater, an optical preamplifier, an optical booster amplifier, and the like.

By the way, when these optical amplifiers are used to output while amplifying the output of an optical transmitter, a high output light of several tens to several hundreds mW is emitted to the output of the optical amplifier. May damage your eyes, and it is necessary to protect your eyes using some means. Therefore,
Conventionally, an optical output automatic lowering circuit for automatically lowering the optical output of an optical amplifier has been used.

FIG. 2 is a block diagram showing an example of such a conventional optical output automatic lowering circuit. In this figure, an optical booster amplifier 102 is connected to the transmission end of the optical transmitter 100, and an optical receiver (not shown) is connected to the reception end of one output port of the optical booster amplifier 102. The optical booster amplifier 102 includes a wavelength division multiplexing (WDM) coupler 121, an Er ³⁺ -doped fiber 122, and an optical coupler 12 that amplifies and outputs the output of the Er ³⁺ -doped fiber 122.
It consists of 3. One input port of the amplifier 160 is connected to one output end of the optical coupler 123 via the optical output monitor circuit 103 that monitors the optical output and the second reference voltage generation circuit 163 that generates the second reference voltage. . The optical output monitor circuit 103 includes a light receiving element 131 and a signal conversion circuit 132. This optical output monitor circuit 10
In No. 3, when it is confirmed that the optical output is above a certain level, the light emitted from the optical coupler 123 is detected by the light receiving element 1.
After receiving light at 31, the signal conversion circuit 132 converts the light into an electric signal. Further, the second reference voltage generation circuit 162 outputs the second reference voltage based on the output of the signal conversion circuit 132, and inputs the reference voltage to the amplifier 160.

At the other output end of the optical coupler 123,
The other input port of the amplifier 160 is connected via the reflected light monitor circuit 104 that monitors the reflected light and the first reference voltage generation circuit 161 that generates the first reference voltage. The reflected light monitor circuit includes a light receiving element 141 and a signal conversion circuit 142. In this reflected light monitor circuit, when it is confirmed that the reflected light is above a certain level, the light emitted from the optical coupler 123 is received by the light receiving element 131, and then converted into an electric signal by the signal conversion circuit 142. Further, in the first reference voltage generation circuit 161, the signal conversion circuit 142
The first reference voltage is output based on the output of the above, and the reference voltage is input to the amplifier 160.

The reference voltage from the reference voltage generating circuit 152 is input to one input port of the comparator 151, and the output voltage of the amplifier 160 is input to the other input port of the comparison 151. The WDM coupler 121 of the optical booster amplifier 102 is connected to the output port of the comparator 151 via the optical output control circuit 106, the drive circuit 107, and the pump laser diode 108. The light output control circuit 10
In 6, the control of the optical output is performed based on the compared output voltage of the comparator 151.

In the drive circuit 107, the light output control circuit 1
Pump laser diode 108 based on the control signal of 06.
Drive. Therefore, in the optical booster amplifier 102,
When the drive circuit 107 is driven, an amplified output having an amplification factor of, for example, 20 dBm is obtained, so that the output voltage supplied from the optical booster amplifier 106 to the optical receiver 110 is lowered by that gain, so that the optical output is automatically output. Can be lowered. When the drive circuit 107 is not driven, no optical signal is sent from the optical transmitter 100 to the optical receiver (not shown) via the optical booster amplifier 102.

FIG. 3 is an example of a block diagram in which the block configuration is simplified from the optical output automatic lowering circuit of the optical fiber amplifier of FIG. The same components as those in FIG. 2 are designated by the same reference numerals, and detailed description thereof will be omitted here.

In FIG. 3, the reflected light monitor circuit 104 is connected to the output end of the optical coupler 123, and the pumping light source monitor circuit 109 is not connected to the output end of the optical coupler 123. Laser light enters the input end of the pumping light source monitor circuit 109 from the output end of the pumping laser diode 108. The excitation light source monitor circuit 109 includes a light receiving element 191.
And a signal conversion circuit 192. The light emitted from the laser diode 108 is received by the light receiving element 191, and then converted into an electric signal by the signal conversion circuit 192.

The reference voltage generation circuit 152 outputs a reference voltage based on the output of the signal conversion circuit 192 and inputs the reference voltage to the amplifier 151. This comparator 151
Outputs a comparison voltage based on the outputs of the reference voltage generation circuit 152 and the signal conversion circuit 142. At this time, the drive circuit 107 drives the pump laser diode 108 to emit light, whereby the pump light source monitor circuit 109 can be operated and the optical booster amplifier 2 can have an amplification factor of, for example, 20 dBm. The output voltage can be lowered by the gain. Therefore, even in the optical output automatic lowering circuit of the optical fiber amplifier of FIG. 3, the optical output can be automatically lowered similarly to the optical output automatic lowering circuit of the optical fiber amplifier of FIG. It is possible to prevent the human eyes that are handled from being adversely affected.

As an example of the optical output automatic lowering circuit of the above optical fiber amplifier, there is JP-A-4-324335. In the optical output automatic lowering circuit of the optical fiber amplifier described in Japanese Patent Laid-Open No. 4-324335,
Similar to the optical output automatic lowering circuit of the optical fiber amplifier shown in FIGS. 2 and 3, when the output end side of the optical amplifier is opened, it is possible to automatically prevent the high optical output from being output from this output end side. As a result, it is possible to eliminate the risk of accidentally getting a high light output into the eyes.

[0012]

In the optical output automatic lowering circuits of these optical fiber amplifiers, the magnitude of the signal light detected by the optical output monitor circuit and the magnitude of the reflected return light detected by the reflected light monitor circuit. The level difference of is obtained by the differential amplifier, and the difference between the level difference in the open state of the output end of the optical amplifier and the reference voltage set to approximately the middle of the level difference in the connected state is compared by the comparator, It was determined whether the output end of the optical amplifier was open or connected. Therefore, in this kind of optical output automatic reduction circuit,
A reference voltage generation circuit is required to compare the difference between the logarithmic amplifier and the reference voltage set to approximately the middle of the level difference in the connected state in order to find the level difference in the open state of the output end of the optical amplifier with a comparator. Therefore, there is a problem that the circuit configuration becomes complicated.

Further, in this type of automatic light output lowering circuit, when a pumping light source monitor circuit for monitoring the state of the pumping light source and a reflected light monitor circuit for monitoring the reflected return light are used, a differential amplifier becomes unnecessary. A reference voltage for determining the open state and the connected state of the output end of the optical amplifier is required from the magnitude of the reflected return light detected by the reflected light monitor circuit. Further, in this optical output automatic lowering circuit, it is necessary to generate two types of reference voltages depending on the state of the excitation light source, and therefore two reference voltage generating circuits must be provided for that purpose, and the area occupied by these circuits must also be considered. There was a problem when trying to miniaturize.

Therefore, it is an object of the present invention to provide an optical output automatic lowering circuit of an optical fiber amplifier which has good operability and maintainability and can be made compact.

[0015]

In order to achieve the above object, the invention according to claim 1 is an optical fiber amplifier for amplifying an optical signal supplied from an optical transmitter, and an optical output for monitoring the optical signal. A circuit for automatically reducing optical output of an optical amplifier, comprising a monitor circuit and a reflected light monitor circuit for monitoring reflected light from an optical output connector at an output end of the optical fiber amplifier,
A part of the optical output of the optical fiber amplifier is monitored by the optical output monitor circuit and converted into a signal. An optical output monitor signal and a part of the reflected light from the optical output connector is monitored by the reflected light monitor circuit and reflected. A comparator that constantly compares the optical monitor signals, a switch that selects which reference voltage to output based on the comparison output of this comparator, and a switch that responds to the first or second reference voltage based on the operation of this switch. The amplification degree of the optical fiber amplifier is controlled.

According to the second aspect of the present invention, the bias circuit is provided with a pump laser diode and a drive circuit for reducing the bias current of the diode.

According to a third aspect of the present invention, the optical output connector is constructed so that when the disconnection of the connector is recovered, the bias current of the pump laser diode and the optical output transmitted from the optical transmitter are automatically restored. To do.

According to the present invention, in the optical fiber amplifier, the input port whose output branching ratio is determined based on the output of the optical amplifier and the photoelectric conversion efficiency of the reflected light monitor circuit and the optical output monitor circuit. And an optical coupler with multiple output ports.

[0019]

According to the present invention, in the reflected light monitor circuit shown in FIG. 1, a voltage fluctuation of about 30 dBm can be expected depending on whether the reflected light monitor voltage is the open state or the connected state of the optical output connector. . In the optical output monitor circuit, the optical output monitor voltage and the reflected light monitor voltage are selected depending on whether the optical connector is open or connected by selecting the set level of the optical output monitor voltage. The relationship of the voltage output level is reversed. In the comparator, a comparison output is obtained by constantly comparing two voltage levels of the reflected light monitor voltage which is the output of the reflected light monitor circuit and the optical output monitor voltage which is the output of the optical output monitor circuit.
In the optical output control circuit, based on the comparison output of the comparator, when the optical output connector is in the connected state, the normal reference voltage is used as the reference voltage, and when the optical output connector is in the open state, it affects the eyes. The switch is switched so that the optical output level is not present and the optical output power becomes the reference voltage at a level at which the optical output can be automatically restored. The light output is automatically controlled based on the reference voltage and the light output monitor voltage thus selected.

According to the second aspect, by providing the pumping laser diode and the drive circuit for reducing the bias current of the diode in the bias circuit, the optical output can be kept at a constant level.

According to the third aspect of the invention, the optical output connector can automatically restore the bias current of the pump laser diode and the optical output transmitted from the optical transmitter when the connector disconnection is recovered. Maintenance work for workers can be done smoothly.

According to a fourth aspect of the present invention, the optical fiber amplifier has a plurality of input ports and a plurality of input ports whose output branching ratio is determined based on the output of the optical amplifier and the photoelectric conversion efficiency of the reflected light monitor circuit and the optical output monitor circuit. By providing the optical coupler having the output port, the optical output can be easily branched.

[0023]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An optical output automatic lowering circuit of an optical fiber amplifier according to the present invention will be described with reference to FIG. Figure 1
It is a block diagram which shows one Example of the optical output automatic reduction circuit of the optical fiber amplifier of this invention. In this example,
The optical amplifier is an optical fiber amplifier, and an Er ³⁺ doped fiber is used as the optical fiber amplifier, and an example in which this is applied to an optical booster amplifier will be described.

In FIG. 1, an optical booster amplifier 2 is connected to the transmission end of the optical transmitter 1, and this optical booster amplifier 2 is connected.
The receiving end of the optical receiver 10 is connected to one of the output ports. This optical booster amplifier 2 has a wavelength division multiplexing (WD
M) coupler 21, Er ³⁺ doped fiber 22, this Er ³⁺
Optical coupler 2 for amplifying and outputting the output of the doped fiber 22
3 and 3.

The optical coupler 23 is provided with four ports, the input port is the port 23a, and the other ports 23b to 23d are the output ports. The optical output from the optical fiber amplifier is input to the port 23a of the optical coupler 23, and the optical signal is converted into an electrical signal to the ports 23b and 23c of the optical coupler 23, and each signal becomes a certain level or higher. An optical output monitor circuit 3 and a reflected light monitor circuit 4 for monitoring the above are connected. An optical connector is provided at the output port of the optical coupler 23 at the output end of the optical fiber amplifier.

In the input port 23a of the optical coupler 23, the output signal of the optical fiber amplifier is output port 23d, and in the output port 23c, the output port 23d is "1".
Branch output is obtained at a ratio of "1" to the output port 23c with respect to "0". At the input port 23a of the optical coupler 23, the reflected return light from the optical connector is branched at a ratio of "10" to the output port 23b with respect to the input port "1". The branching ratio of the optical coupler 23 is determined by the output of the optical fiber amplifier and the optical-electrical conversion efficiency of the optical monitor circuit, and thus other branching ratios can be used.

Further, one output port of the optical coupler 23 is connected to one input port of the comparator 5 via the optical output monitor circuit 3 for monitoring the optical output. The optical output monitor circuit 3 includes a light receiving element 31 and a signal conversion circuit 32. The optical output monitor circuit 3 monitors the magnitude of the signal from the optical fiber amplifier. In this optical output monitor circuit 3, when it is confirmed that the optical output is above a certain level, the light emitted from the optical coupler 23 is received by the light receiving element 3
After receiving light at 1, the signal conversion / amplification circuit 32 obtains an amplified output converted from current to voltage.

The other output port of the optical coupler 23 is connected to the other input port of the comparator 5 via the reflected light monitor circuit 4 for monitoring the reflected light. This reflected light monitor circuit 4
Is composed of a light receiving element 41 and a signal conversion circuit 42.
The reflected light monitor circuit 4 monitors the magnitude of the reflected return light from the optical connector at the output end of the optical fiber amplifier. When it is confirmed that the reflected light is above a certain level, the light emitted from the optical coupler 23 is received by the light receiving element 31 and converted into an electric signal, and then the signal conversion / amplification circuit 4
At 2, an amplified output converted from current to voltage is obtained.

The monitor output of the reflected light monitor circuit 4 is input to one input port of the comparator 5, and the monitor output of the optical output monitor circuit 3 is input to the other input port. The comparison cormorator 5 outputs a comparison output based on the output from the reflected light monitor circuit 4 and the output from the optical output monitor circuit 3 to the optical output control circuit 6.

The optical output control circuit 6 includes a first basic forward voltage generating circuit 61 for generating a first reference voltage based on the comparison output of the comparator 5 and a second reference voltage generating circuit for generating a second reference voltage. 62, a switch 63 for switching between the first reference voltage generating circuit 61 and the second reference voltage generating circuit 62, and a first or second reference voltage generated by the switching operation of the switch 63 is input to one input port. And an amplifier 64 for supplying the output of the optical output monitor circuit 3 to the other input port.

The drive circuit 7 drives the pump laser diode 8 based on the control signal from the light output control circuit 6. Therefore, in the optical booster amplifier 2, when the drive circuit 7 is driven, an amplified output having an amplification factor of, for example, 20 dBm is obtained, so that the optical booster amplifier 6 to the optical receiver 10
Since the output voltage supplied to is low by that gain,
The light output can be reduced automatically. When the drive circuit 7 is not driven, no optical signal is sent from the optical transmitter 10 to the optical receiver 10 via the optical booster amplifier 2.

Therefore, in the optical output automatic lowering circuit of the optical fiber amplifier of FIG. 1, the optical output can be automatically lowered, so that the human eyes handling the optical fiber amplifier are not adversely affected. Not only can this be done, but the circuit configuration can be made compact.

Next, the operation of the present invention will be described with reference to FIG. The signal input from the optical transmitter 1 is assumed to output +15 dBm at the output end by the optical fiber amplifier. When the optical connector that is the output end of the optical fiber amplifier is connected to the transmission line, the reflected return light from that output end becomes -14 dB (about 0.1% return light), and when it is open. Is described as -14 dB (return light of about 4%), the connection loss of the optical fiber 22 and the insertion loss of the optical coupler 23 are ignored for simplicity. In addition, the light receiving elements 31 in the optical monitor circuits 3 and 4,
The optical-electrical conversion efficiency of 41 is 1 A / W, and the outputs of the two optical monitor circuits 3 and 4 are reversed in magnitude relationship depending on whether the output of the optical connector circuit is open or connected. As described above, the impedance gains of the two current-voltage conversion amplifiers are set to, for example, 1.27 kΩ for the optical output monitor and 4.39 kΩ for the reflected light monitor.

First, the optical connector output is +15 dBmn.
At this time, if the output end of the optical amplifier is connected to the transmission line, the optical output monitor voltage is -4V and the reflected light monitor voltage is -0.1V, which is higher than the optical output monitor voltage. Has a higher voltage. At this time, the comparator 5
The optical output control circuit 6 selects the first reference voltage from the output control signal of + 15d as the optical connector output.
The drive current of the pump laser diode 8 is controlled so that Bm is output.

Next, at the moment when the optical connector is opened, the reflected return light increases, so that the reflected light monochromatic voltage becomes
It becomes −5.0 V, and the magnitude relationship between the optical output monitor voltage and the reflected light monitor voltage is reversed. As a result, the output control signal of the comparator 5 changes, and the optical output control circuit 6 dedicates the second reference voltage to the drive circuit 7 so as to reduce the output level output from the optical fiber amplifier. It is driven to control the drive current of the pump laser diode 8. Here, it is assumed that the output is constantly controlled to +5 dBm. The light output level at this time is controlled to a level that does not affect the human body, and is not limited to +5 dBm, but may be any level that does not affect the human body.

Next, at the moment when the optical connector is connected to the transmission line again, the reflected return light is reduced and the reflected light monitor voltage becomes -0.01 V and the optical output monitor voltage becomes -0.4 V. The magnitude relationship of the reflected light monitor voltage is reversed again. As a result, the optical output control circuit 6 drives the drive circuit 7 again so that a constant output of +15 dBm is obtained as the optical connector output, and controls the drive current of the pump laser diode 8.

As described above, in the present embodiment, the light output monitor voltage and the reflected light monitor voltage are always compared in size by the comparator 5, and the light output control circuit 6 is reversed by reversing the size relationship. The light output control signal of is changed. In the optical output control circuit 6, the optical output control signal selects and outputs either one of the normal output level and the low output level.

In the optical output control circuit 6 of the present embodiment, one optical reference voltage is used because it is an optical fiber amplifier controlled so that the optical output is constant. However, the present invention is not limited to this and, for example, When the mark ratio, which is the ratio of the data signal “1” and the data signal “0” of the optical transmitter 1, is compensated, the mark ratio compensation output is obtained by using the voltage having the mark ratio information as the reference voltage. The present invention can also be applied to an optical fiber amplifier that can be controlled to be constant.

[0039]

As described above, in the optical output automatic lowering circuit of the optical fiber amplifier according to claims 1 to 4,
When the optical connector, which is the output end of the optical fiber amplifier, is in the open state, the optical output level can be automatically reduced. Therefore, by mistakenly attaching or detaching the optical connector, the high level laser is mistakenly viewed directly. It is possible to avoid such a possibility, and since it is possible to automatically return to the normal level by connecting to the transmission line again, it is not necessary to turn on and off the power supply of the device, so that operability can be improved, Further, since the logarithmic amplifier and the reference voltage generating circuit are unnecessary for determining the open state or the connected state of the optical connector, the circuit configuration can be simplified.

Particularly, in the invention described in claim 1, since the light output can be automatically controlled, the operability can be improved and the circuit configuration can be simplified.

According to the present invention, the bias circuit is provided with the pump laser diode and the drive circuit for reducing the bias current of the diode.
The light output can be at a constant level.

Further, according to the third aspect of the present invention, when the disconnection of the connector is recovered, the bias current of the pump laser diode and the optical output transmitted from the optical transmitter can be automatically restored. Maintenance work for personnel can be performed smoothly. According to the invention of claim 4, the optical output can be easily branched.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of an optical output automatic lowering circuit of an optical fiber amplifier according to the present invention.

FIG. 2 is a block diagram showing an example of an optical output automatic lowering circuit of a conventional optical fiber amplifier.

FIG. 3 is a block diagram showing an example of an optical output automatic lowering circuit of a conventional optical fiber amplifier.

[Explanation of symbols]

 1 Optical Transmitter 2 Optical Booster Amplifier 3 Optical Output Monitor Circuit 4 Reflected Light Monitor Circuit 5 Comparator 6 Optical Output Control Circuit 7 Drive Circuit 8 Excitation Laser Diode 10 Optical Receiver

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[Procedure amendment]

[Submission date] February 3, 1995

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

Patent application title: Optical output automatic lowering circuit of optical amplifier

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical output automatic lowering circuit of an optical amplifier, which has a function of protecting a human eye and the like from an optical output output from an optical fiber amplifier constituting an optical communication system. The present invention relates to a circuit for automatically lowering the optical output of an optical amplifier when the output end of the optical amplifier is open.

[0002]

2. Description of the Related Art Generally, an optical amplifier is a semiconductor optical amplifier,
There are three optical amplifiers, a rare earth doped fiber optical amplifier and a Raman optical amplifier. Similar to the laser diode, the semiconductor optical amplifier utilizes the gain mechanism of the semiconductor active layer by current injection, operates the device below the oscillation threshold value, and obtains the optical amplification effect for the injection light from the outside. A rare-earth-doped fiber optical amplifier uses an optical fiber in which a core element of the fiber is doped with an earth element such as Ed ³⁻ or Er ³⁺ as an amplifying medium. In particular, an Ed ³⁺ doped optical fiber has a wavelength of 1.55 μm Has a laser transition frequency at
Since optical amplification in that wavelength range is possible, application to optical communication systems can be expected. Further, in the Raman optical amplifier, an amplification effect is obtained by utilizing the stimulated Raman scattering phenomenon, which is a non-linear optical effect, in the process of converting the optical power from the pump light to the signal light. As an application form of these optical amplifiers to an optical communication system, they are applied to an optical amplification repeater, an optical preamplifier, an optical booster amplifier, and the like.

By the way, when these optical amplifiers are used to output while amplifying the output of an optical transmitter, a high output light of several tens to several hundreds mW is emitted to the output of the optical amplifier. May damage your eyes, and it is necessary to protect your eyes using some means. Therefore,
Conventionally, an optical output automatic lowering circuit for automatically lowering the optical output of an optical amplifier has been used.

2 and 3 show a conventional optical output automatic low.
It is a block diagram which shows the example of a lower circuit. In these figures and
The optical booster amplifier 2 is connected to the transmitting end of the optical transmitter 1.
The optical transmission line is connected to the output port of this optical booster amplifier 2.
(Not shown) is connected.

The optical booster amplifier 2 is output from the optical transmitter 1.
Input signal light and pumping light output from pumping light source 8
Wavelength multiplexing (WDM) coupler 21, Er ³⁺ doped fiber
It is composed of an aver 22 and an optical coupler 23.

First, the optical output automatic lowering circuit of FIG.
Monitors the magnitude of the signal light output from the star amplifier 2.
Optical output monitor circuit 3 and the output end of the optical booster amplifier 2
Reflected light monitor to monitor the magnitude of reflected light from
Path 4, optical output monitor circuit 3 and reflected light monitor circuit 4
A logarithmic amplifier 101 for logarithmically converting the received light power detected by
102 and the output from these logarithmic amplifiers 101 and 102.
The difference between the magnitude of the reflected light output and the magnitude of the reflected light is calculated.
Arithmetic circuit 100 and a reference voltage generator for outputting a predetermined reference voltage.
The difference value obtained by the raw circuit 52 and the arithmetic circuit 100
The arithmetic circuit 51 for comparing with the reference voltage and the arithmetic circuit 51
Drive circuit that controls the current supplied to the pumping light source by the output
It was composed of 7.

The optical output automatic lowering circuit shown in FIG.
Excitation light source for monitoring the state of the excitation light source 8 of the star amplifier 2
The output from the monitor circuit 9 and the output end of the optical booster amplifier 2
A reflected light monitor circuit 4 for monitoring the magnitude of reflected light,
Light emission of the excitation light source 8 monitored by the excitation light source monitor circuit 9.
Power level, that is, the optical output level of the optical booster amplifier 2
A reference value generating circuit 52 for generating a reference value having a corresponding size.
And the magnitude of the reflected light detected by the reflected light monitor circuit 4
Arithmetic circuit 5 for comparing with a reference value from reference value generating circuit 52
1 and supply to the pumping light source 8 by the output of the arithmetic circuit 51
It is composed of the drive circuit 7 for controlling the current to be applied.

[0008]

The conventional light shown in FIG .
In the optical output automatic lowering circuit of the amplifier, the optical booster amplifier 2
The optical output mode is used to determine the connection and release status of the output end of
Magnitude of signal light monitored by Nita circuit 3 and reflected light monitor
Calculate the difference from the magnitude of the reflected return light monitored by circuit 4.
Therefore, the difference output in each state of connection and release is almost
Set a reference voltage in the middle and compare these two signals.
It is necessary to judge the connection or release status with and.

That is, the signal received by the optical output monitor circuit 3
Light intensity and reflected return light received by the reflected light monitor circuit 4.
A logarithmic operational amplifier is required to obtain the difference in the magnitude of
Yes, and determine whether it is in connection or release
Requires a reference value generation circuit to generate a reference voltage
However, there is a problem that the circuit becomes complicated.

The optical output of the optical amplifier shown in FIG.
In the lower circuit, connection and solution at the output end of the optical booster amplifier 2
A reflected light monitor circuit that monitors the reflected return light in the released state
The magnitude of the reflected return light from 4 and the reference voltage generating circuit 52
It is judged by comparing with the reference voltage output from
It

The reference voltage generating circuit 52 is an optical booster.
The correlation between the optical output of the amplifier 2 and the optical output of the pumping light source 8
Excitation by monitoring the magnitude of the optical output of the excitation light source 9 using
Generates a reference voltage based on the output signal of the light source monitor circuit 9.
I am letting you.

That is, the reference voltage is the light of the optical booster amplifier 2.
Reflection at connection and release at the output end depending on the output level
It is set to the middle of the return light level.

In this way, the optical output of the optical booster amplifier 2 is
By monitoring the optical output of the pumping light source 8
Since it is sought, wavelength division multiplexing (WDM) coupler 21
The reference voltage shifts due to temperature characteristics or deterioration of the excitation light source 8
There is a problem that the connection / release status of the force end is erroneously determined.
It was.

[0014]

The light output of the optical amplifier of the present invention
The automatic power reduction circuit outputs the optical signal supplied from the optical transmitter.
The optical amplifier that amplifies the signal as it is and the optical signal and
And a light component that splits the reflected return light from the output end at a fixed rate.
And optical signal of the branched optical amplifier is converted to optical-electrical signal.
Optical output monitor circuit and reflected return from the branched output end
A reflected light monitor circuit that converts light to an electrical signal and this light
The magnitude of the optical signal detected by the output monitor circuit and the reflected light monitor
Comparing the magnitude of the reflected return light detected by the digital circuit
Amplifier and optical amplifier based on the output signal level of this comparator
From the optical output control circuit that controls the output level of the optical signal of
Composed.

Here, the optical output control circuit is the optical signal of the optical amplifier.
No. 1 and No. 1 for generating a reference voltage according to the signal output level
Based on the reference signal generator circuit of 2 and the output signal level of the comparator.
Either the first reference voltage or the second reference voltage
The switch selected as the reference voltage and this switch
The amplification factor of the optical amplifier is controlled based on the selected reference voltage.
It is composed of an optical amplifier drive circuit.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An optical output automatic lowering circuit of an optical amplifier according to the present invention will be described.
It will be described with reference to FIG. FIG. 1 shows the optical amplification of the present invention.
FIG. 3 is a block diagram showing an embodiment of an optical output automatic lowering circuit of a container.
is there. In this embodiment, an Er ³⁺ doped fiber is used as an optical amplifier.
The optical fiber amplifier used was applied to the optical booster amplifier.
The case will be described.

In FIG . 1, an optical block is provided at the transmission end of the optical transmitter 1.
The booster amplifier 2 is connected to this optical booster amplifier 2.
A transmission line is connected to the output end. This light booster
The amplifier 2 includes a wavelength division multiplexing (WDM) coupler 21 and Er ³⁺ addition.
Additional fiber 22, excitation light source (excitation laser) 8 and optical power
It is composed of a plastic 23.

This optical coupler 23 has four ports
And port "1" connects to Er ³⁺ doped fiber
And port "2" is connected to the output end,
The port "3" is connected to the optical output monitor circuit 3,
The port “4” is connected to the reflected light monitor circuit 4.
Here, the optical signal incident from the port “1” is
It is branched to port "2" and port "3". here
Is 90 for port "2" and 10 for port "3"
It will vary. In addition, the anti-light incident from the port "2"
Similarly, the reflected light returns to port “1” and port at a constant rate.
It is branched to “4”. Here, 10 on port "1",
It is assumed that the port “4” branches at a rate of 90. Na
The branching ratio of the optical coupler depends on the optical output monitor circuit 3 and reflection.
Determined by the light-to-electricity conversion efficiency of the light monitor circuit 4.
Therefore, it is not limited to the branch of this embodiment.

The signal light input from the optical transmitter 1 is an optical signal.
Outputs +15 dBm at the output end with a fiber amplifier
I shall. Also, the optical fiber that is the output end of the optical fiber amplifier
If the connector is connected to the transmission line,
The reflected return light is -30 dB (about 0.1% return light),
-14 dB (about 4% return light) when released
The optical fiber splice loss and
And the insertion loss of the optical coupler is neglected for simplicity.

The signal light output from the optical fiber amplifier
The reflected light and the reflected return light are photoelectrically converted by the light receiving element, and
The optical output monitor voltage and
It is output as the reflected light monitor voltage. Two monitor voltages
Is input to the comparator 5 and the size is compared to determine the optical connector.
Release or connection status is determined.

Light-electricity of the light receiving element in the optical monitor circuits 3 and 4.
The gas conversion efficiencies are both 1 A / W and the two
The outputs of the optical monitor circuits 3 and 4 are connected when the optical connector is released and connected.
Depending on the condition, the two current-voltage may be reversed so that the magnitude relationship is reversed.
The transimpedance gain of the conversion amplifiers 32 and 42
1.27 kΩ for optical output monitor, 4. for reflected light monitor.
It was set to 39 kΩ.

Hereinafter, each state of the optical booster amplifier of this embodiment will be described.
The operation in the state will be described.

First, the optical connector output is +15 dBm
When the output end is connected to the transmission line, the optical output
The monitor voltage is -4V and the reflected light monitor voltage is -0.1V.
The reflected light monitor voltage is better than the optical output monitor voltage.
growing.

At this time, light is output from the output control signal of the comparator 5.
The constant force control circuit shall select the reference voltage 1, and
Excited to output a constant +15 dBm as the nectar output
Controls the drive current of the laser diode.

Next, the moment when the optical connector is released,
During this period, the reflected light monitor voltage is-
0.5V, optical output monitor voltage and reflected light monitor voltage
The size relationship of is reversed. This controls the output of the comparator 5.
The signal changes and the optical output constant control circuit selects the reference voltage 2.
Output signal from the optical fiber amplifier.
The driving voltage of the pumped laser diode is reduced so as to reduce the bell.
Control the flow. Here, the output of +5 dBm is constantly controlled.
Shall be.

At this time, the optical output monitor voltage is -0.4V,
The reflected light monitor voltage is -0.5V, and the output of + 5dBm.
Constant force control is maintained.

Next, the light output level at this time is reflected on the human body.
It controls to a level that does not give a sound, +5 dBm
Not limited to

Then, again, the optical connector is connected to the transmission line.
At the moment when the
The pressure is -0.01V and the optical output monitor voltage is -0.4V.
The relationship between the optical output monitor voltage and the reflected light monitor voltage is
Reverse again. As a result, the constant light output control circuit again
As +15 dBm constant output as optical connector output
Control the drive current of the pump laser diode.

As described above, the optical output monitor voltage and reflection
Optical monitor voltage is always compared in magnitude, and the relationship is reversed.
As a result, the output control signal of the comparator changes. To this signal
The more constant light output control circuit has the normal level and the low output level.
Select one of the two output levels and output.

Reference voltage of the optical output constant control circuit of this embodiment
Is an optical fiber amplifier with constant optical output control.
Data signal of optical transmitter "1"
When compensating for the mark ratio, which is the ratio of
Use the voltage with the peak rate information as the reference voltage
So, even for an optical fiber amplifier with constant mark ratio compensation output control
Applicable.

[0031]

As described above, according to the optical fiber amplifier of the present invention,
The constant optical output control circuit is the output end of the optical fiber amplifier.
When the optical connector is released, the optical output level
The optical connector is installed and removed in order to reduce it dynamically.
If you accidentally look directly at a high-level laser when removing it, etc.
It is possible to avoid such a danger and to connect to the transmission line again.
And to automatically return to the normal light output level,
The effect that it is very easy to handle because there is no need to cut the source
There is a fruit. It is also useful for determining the release / connection status of optical connectors.
No need for several amplifiers and reference voltage generator
This has the effect of making it easier.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of an optical output automatic lowering circuit of an optical fiber amplifier according to the present invention.

FIG. 2 is a block diagram showing an example of an optical output automatic lowering circuit of a conventional optical fiber amplifier.

FIG. 3 is a block diagram showing an example of an optical output automatic lowering circuit of a conventional optical fiber amplifier.

[Explanation of symbols] 1 optical transmitter 2 optical booster amplifier 3 optical output monitor circuit 4 reflected light monitor circuit 5 comparator 6 optical output control circuit 7 drive circuit 8 pump laser diode 10 optical receiver

[Procedure Amendment 2]

[Document name to be corrected] Drawing

[Correction target item name] All drawings

[Correction method] Change

[Correction content]

[Fig. 2]

[Figure 1]

[Figure 3]

Claims (4)

[Claims] 1. An optical fiber amplifier for amplifying an optical signal supplied from an optical transmitter, an optical output monitor circuit for monitoring the optical signal, and a reflected light from an optical output connector at an output end of the optical fiber amplifier. A reflected light monitor circuit for monitoring, an optical output monitor signal obtained by converting a part of the optical output of the optical fiber amplifier by the optical output monitor circuit, and a part of the reflected light from the optical output connector. A comparator that constantly compares the reflected light monitor signal that is monitored by the optical monitor circuit and converted into a signal, a switch that selects which reference voltage to output based on the comparison output of this comparator, and a switch that operates based on the operation of this switch. And a bias supply circuit that outputs a reference voltage according to the first or second reference voltage to control the amplification degree of the optical fiber amplifier. Lowering circuit. 2. The optical output automatic lowering circuit for an optical amplifier according to claim 1, wherein the bias circuit includes an excitation laser diode and a drive circuit for reducing a bias current of the diode. 3. The optical output connector is characterized in that when the disconnection of the connector is recovered, the bias current of the pump laser diode and the optical output transmitted from the optical transmitter are automatically restored. An optical output automatic lowering circuit of the optical amplifier according to claim 1 or 2. 4. The optical fiber amplifier includes an input port and a plurality of outputs whose output branching ratio is determined based on the output of the optical amplifier and the photoelectric conversion efficiency of the reflected light monitor circuit and the optical output monitor circuit. An optical output automatic lowering circuit for an optical amplifier according to claim 1, wherein an optical coupler having a port is provided.