JP3050237B2 - Control method of optical amplifier and optical amplifier - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Summary of the Invention] An optical amplification fiber doped with a rare earth element for the purpose of detecting a state where an input signal to an optical amplifier is cut off and preventing noise light from being output. In the optical amplifying device using, the disconnection of the input light to the optical amplification fiber is detected, and the power of the excitation light supplied to the optical amplification fiber is suppressed or the supply of the excitation light is stopped by the input disconnection detection output. The configuration is as follows.

[Industrial applications]

The present invention relates to a method for controlling an optical amplifier used in an optical transmission system and an optical amplifier.

Pumping light (pumping light) is input together with an optical signal into an optical fiber doped with a rare earth element such as erbium,
2. Description of the Related Art An optical amplifier that amplifies an optical signal as light and outputs the amplified signal is known. As a method for searching for a fault point in an optical transmission system using this optical amplifier as an optical amplification repeater, for example, an optical submarine transmission system, an optical loopback method is being studied. In this case, noise may be input from the opposite line at the time of loopback, and a countermeasure is required. Hereinafter, an optical submarine transmission system will be described as an example, but the present invention can of course be applied to a land-based optical transmission system.

[Conventional technology]

FIG. 4 shows an outline of the optical submarine transmission system. L ₁ and L ₂ are upstream and downstream optical submarine cables at predetermined intervals
REP (subscripts 1, 2,... Are omitted as appropriate) is inserted.

In this optical submarine transmission system, a loopback that is also performed in a land-based optical transmission system is being studied for searching for a fault point. For example, there is no abnormality in the transmission signal loops back LB with repeaters REP _1, end station A- uplink L ₁ - repeater REP ₁ -LB
- relay REP ₄ - downlink L ₂ - in the path of the terminal station A is not without fault. Next, loop back in REP ₂ and if there is any abnormality, the fault can be identified as this section.

To do this loopback, the terminal station (land station) A request to stop signal transmission of from loops back to the downlink L ₂ to the terminal station B, and the repeater present example Thereafter loopback REP ₁ to tell the loopback (since in each repeater are designated by the address, sends a loopback command marked with the appropriate address to the uplink L _1). In this example, REP ₁ is the downlink repeater of the own station.
To P _4, enter the optical signal transmitted through the uplink L ₁ from the terminal station A, is sent back to the end station A through the downlink L _2.

[Problems to be Solved by the Invention] By the way, when such a loopback is performed, the terminal station B
In Stop signal transmission to the downlink L _2, since each optical amplifier repeater is APC (Automatic Power Control) function, the noise is generated gain up, which is input to the repeater REP ₄ Mixing with the looped-back signal, the loopback signal received at the terminal A has a very poor S / N.

This is because, when the optical signal input to the optical amplifier is interrupted, the gain increases and noise is output. This problem must be considered especially when excitation light is input to an optical fiber in which an optical amplifier is doped with a rare earth element such as erbium having a long fluorescence lifetime to activate the rare earth element and perform induced amplification. In order to solve this problem, the present invention provides a function of detecting an input signal disconnection state in each optical amplifier, and limits an increase in gain of the optical amplifier when an input signal disconnection state is detected.

Then, for example, it is possible to reliably perform a failure search by optical loopback.

[Means for solving the problem]

As shown in FIG. 1, in the present invention, an optical amplifier (optical repeater) is used.
REP) is provided with an input disconnection detection circuit 22, and the driver 19 of the pumping light source 20 receives the input disconnection detection output of the detection circuit to suppress or stop the output of the excitation light. Provide a function to suppress or stop.

As shown in FIG. 2, in the present invention, a limiter 23 is added to the control signal circuit of the automatic power control circuit (APC) 18 for inputting a control signal to the driver 19 of the pumping light source 20 of the optical amplifier (optical repeater REP). Insert

As in all the drawings, the same parts as those in the other drawings are denoted by the same reference numerals. “ _I ” of the repeater REP _i is the repeater inserted into the upstream optical cable (optical submarine cable), and the RE
“ _J ” of P _j indicates a repeater inserted into a downstream optical cable. The optical repeaters REP _i and REP _j are of an optical direct amplification type using an erbium-doped fiber.

[Embodiment of the invention]

FIG. 1 and FIG. 2 are block diagrams showing an embodiment of the optical amplifying device of the present invention.

In this optical amplifying repeater, a part of the optical output extracted by the beam splitter 14 is guided to the beam splitter 15, and a part thereof is further input to the optical / electrical converter 16, where the optical signal is converted into an electric signal. And input to APC18. In the APC 18, a control signal for keeping the light output at a predetermined value is input to the driver 19, so that the driver 19 increases or decreases the driving current of the pumping light source 20 so that the light output holds the predetermined value. .

When the optical output of such an optical amplifier repeater is interrupted by the above-described loopback control or the like, the APC 18 increases the drive current so as to keep the optical output still constant. The pumping light source 20, which is a laser diode, receives this and generates extraordinarily strong pumping light, which is input to the erbium-doped fiber 13 through the coupler 12. For this reason, in the related art, the gain of the optical amplifier increases, and noise is generated.

In FIG. 1, a part of the optical input is taken into an optical / electrical converter 21 by a coupler (beam splitter) 11, where the optical signal is converted into an electric signal and supplied to an input disconnection detection circuit 22 to monitor the optical input. . When the interruption of the light input is detected, the circuit 22 outputs the detection signal, and the driver 19 cuts off the drive current of the pumping light source 20 when receiving the signal. As a result, the pumping light disappears, the gain of the erbium-doped fiber 13 disappears, and noise generation is avoided.

In FIG. 2, when the optical input is cut off, the APC 18 maximizes the control signal and causes the driver 19 to maximize the drive current of the pumping light source. However, since the limiter 23 is included in the control signal circuit, this limiter controls the control signal. By limiting the maximum value of the signal and thus the drive current, the pumping light is suppressed to an appropriate level, and the noise output by the repeater is suppressed, for example, to a level that does not hinder optical loopback.

In FIG. ₄ , the repeater inserted in the downstream optical submarine cable between the terminal station B and the repeater REP ₄ causes the problem of noise generation when the optical signal input is interrupted due to the loopback. However, the loopback is performed by an arbitrary repeater, and when the loopback is instructed from the terminal station B, the loopback from the downstream optical submarine cable to the upstream optical submarine cable is performed.
The function shown in the figure is provided in the all-optical amplification repeater. Up /
Downlink is a name for convenience of the cables L ₁ and L ₂ , and when viewed from the terminal A, the optical cable L ₁ is a transmission line and the optical cable L ₂
The receiving line, the cable L ₁ when viewed from the terminal station B is the received-side line, cable L ₂ is a transmitting-side line.

Loopback is performed by opening the optical shutter 17. Thus, in FIG. 1, a path of 11-12-13-14-15-17-REP _j is created, and loopback from the upstream optical submarine cable to the downstream optical submarine cable is performed. Loopback to the downstream optical submarine cable is conducted through the optical cable 1 _a. The repeater REP _{j in the} opposite direction (downstream optical submarine cable) has the same configuration as the upstream optical submarine cable repeater REP _i, and has a coupler 11 of REP _i .
(Not shown). The optical cable 1 _a is,
Pass the output of the optical shutter 17 (not shown) of REP _j . Figure 3 of the REP ₂ is REP _i, REP ₃ corresponds to REP _j, input break detection circuit 22 of REP _j to detect input interruption during loopback of REP _j to the drive current to cross driver 19

FIG. 3 shows an embodiment of each part. FIG. 3A shows an embodiment of the input disconnection detection circuit 22, which includes a band-pass filter (MCF filter) 22a, a peak detection circuit 22b, and a comparator 22.
Consists of c. The peak detection circuit consists of a diode D ₁ and a capacitor C ₁ , and the comparator is an operational amplifier DA ₁ and a resistor R
_1, composed of R _2, PT.

After the output from the optical / electrical converter 21 is passed through a filter 22a to remove noise and the like, a peak is detected by a circuit 22b, and the output is guided to a comparator 22c through a resistor R1, and used as _one input. The other input is the potentiometer PT
There is an output to the threshold voltage V _t. Since the differential amplifier DA ₁ gain is sufficiently high, and since the feedback due to the resistance R ₂ is hanging, operates as the one and the input of the other are substantially equal. Assuming that R ₁ = R ₂ for simplicity, if the output of the peak detection circuit is 0 due to input interruption, the output of DA ₁ will be 2 _Vt , and if there is an optical input and the output of the peak detection circuit is lower than this (e.g. peak 0 output output of DA ₁ if 2V _t is detector) i.e., the comparator 22c, the beam splitter 11
The light input level branched by is compared with a threshold (Vt),
It operates so as to generate an output when it becomes equal to or less than the threshold.
This comparator output is input to the APC 18 in this example.

Third automatic power control as shown in Figure (b) (APC) circuit 18 is a photodiode D _2, the differential amplifier DA _2, resistors R ₃ to R
_6, PT ₂ consists of capacitor C _2. The driver 19, a transistor Q, the resistor R ₇ of the emitter circuit for driving a laser diode (pumping light source) 20.

The output from the optical / electrical converter 16 enters the differential amplifier DA ₂ through the resistor R _5, it becomes one input V _i of the amplifier. The other input is a reference voltage V _R output from the potentiometer PT _2, the differential amplifier DA ₂ turns on the transistor Q so that the V _i ≒ V _R, thus the optical power of the laser diode 20 outputs a constant Control. The output light of the laser diode 20 is also input to the photodiode D _2, changing the degree of conduction, adding local negative feedback. The power supply of this local feedback circuit is the output of the input disconnection detection circuit 22, which is low during normal operation and becomes a high voltage upon input disconnection, so that negative feedback works strongly. Therefore, when the input is cut off, DA ₂
Works because the laser diode 20 (pumping light source)
Light emission (light output) is suppressed. In this embodiment, the drive current of the laser diode is not cut off and light emission is not stopped. However, noise can be avoided by sufficiently controlling light emission. Of course, as described in connection with FIG. 1, the drive current of the laser diode 20 may be cut off to stop the light emission.

In FIG. FIG. 3 (c) is showing an example of the limiter 23, which is composed of a diode D _3, resistors R _8, R _9, PT _3, is inserted between the APC circuit and the driver as shown .

The input interruption of the optical signal, the output of the APC circuit to increase the gain becomes large, the diode D ₃ exceeds the set value by potentiometer PT ₃ is turned on to limit the control voltage to be supplied to the driver.

〔The invention's effect〕

As described above, in the present invention, the optical output of the pumping light source is cut off or suppressed when it is detected that the power of input light to the optical amplification fiber having a long fluorescence lifetime doped with a rare earth element is equal to or less than a predetermined value, Since the gain is reduced to 0 or reduced, it is possible to prevent the optical amplification repeater from outputting noise. For this reason, failure search by optical loopback
It can be performed reliably without bothering S / N degradation.

[Brief description of the drawings]

1 and 2 are block diagrams showing optical amplifier repeaters 1 and 2 of the present invention, FIG. 3 is a circuit diagram showing an embodiment of each unit, and FIG. 4 is an explanatory diagram of an optical submarine transmission system. 1 and 2, 22 is an input disconnection detection circuit, 19 is a driver, 20 is a pumping light source, 18 is an automatic power control circuit, 23
Is a limiter.

 ──────────────────────────────────────────────────続 き Continuation of front page (56) References Patent 2597748 (JP, B2)

Claims (8)

(57) [Claims] When the power of input light to an optical amplification fiber doped with a rare earth element is detected to be equal to or less than a predetermined value, the power of pump light supplied to the optical amplification fiber is suppressed. A method for controlling an optical amplifier, comprising: 2. When the power of the input light to the optical amplification fiber doped with the rare earth element is detected to be equal to or less than a predetermined value, the supply of the pump light to the optical amplification fiber is stopped. A method for controlling an optical amplifying device. 3. A detection circuit for outputting a disconnection detection signal of an input light based on a comparison result between a power of an input light to a rare earth element-doped optical amplification fiber and a threshold value, and responding to the disconnection detection signal. Means for suppressing the power of the pump light supplied to the optical amplification fiber. 4. The optical amplifying apparatus according to claim 3, wherein said suppressing means limits a current for driving an excitation light source for outputting said excitation light. 5. A detection circuit for monitoring a state of input light to an optical amplification fiber doped with a rare earth element, and supply of pump light to the optical amplification fiber is stopped based on a monitoring result of the detection circuit. And an optical amplifying device. 6. A detection circuit for outputting a disconnection detection signal of an input light based on a comparison result between a power of an input light of a rare earth element-doped optical amplification fiber and a predetermined value, and responding to the disconnection detection signal. Means for stopping supply of pumping light to the optical amplification fiber. 7. The optical amplifying device according to claim 5, wherein said stopping means stops supplying a current for driving an excitation light source for outputting said excitation light. 8. An automatic power control circuit for controlling the power of the pumping light to control the power of the output light of the optical amplifying fiber.
The optical amplifying device as described in the above.