JP2546494B2 - Bidirectional pumping optical amplifier - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bidirectional pumping optical amplifier, and more particularly to an optical amplifier suitable for being installed in a signal transmission line in which an upstream line and a downstream line are arranged in parallel.

[0002]

2. Description of the Related Art Conventionally, when an optical amplifier is formed in an optical fiber as a signal transmission line, an optical fiber doped with a rare earth element such as erbium or an ion has been used. By inputting, the signal light can be amplified. In this case, generally, the pumping light and the signal light are combined on the input side of the optical fiber and the combined light is input to the optical fiber. At the same time, the pumping light is input from the output side of the optical fiber. Directional pump optical amplifiers have also been proposed. In this way, by inputting pumping light from both the front and the back of the optical fiber, even if the input of either pumping light is blocked, the amplification is secured by the other pumping light, and the reliability of the amplifier is improved. The advantage is that it can be increased.

For this reason, such a bidirectional pumping optical amplifier is also used in an optical transmission line such as a submarine optical cable. FIG. 3 is a configuration diagram of an example thereof, in which an upstream line 100 and a downstream line 200 are installed in parallel as an optical cable for transmitting a signal light, and an erbium-doped optical fiber (EDF: EDF: Hereinafter, simply referred to as an optical fiber) 10 and 20 are inserted. In the upstream line 100, the isolator 1 is provided on the front side of the optical fiber 10.
1 and a wavelength synthesizer (hereinafter, simply referred to as a wavelength synthesizer) 12 having a wavelength synthesizing / separating function, and a laser diode 13 as an excitation light source is provided in the wavelength synthesizer 12.
Are connected via an isolator 14. Similarly, the wavelength synthesizer 15 and the isolator 1 are provided on the rear side of the optical fiber 10.
6, a laser diode 17 as an excitation light source is connected to the wavelength synthesizer 15 via an isolator 18. The same applies to the downlink 200, in which the wavelength synthesizers 22 and 25 and the isolators 21 and 26 are inserted on the front side and the rear side of the optical fiber 20, respectively, and the wavelength synthesizers 12 and 15 include the isolators 14 and 1, respectively.
The excitation light sources 13 and 17 are connected via 8.

By constructing such a bidirectional pumping optical amplifier, for example, in the upstream line 100, the signal light input from the input terminal IN1 is combined with the pumping light from the pumping light source 13 in the wavelength combiner 12 to form an optical fiber. It is input to 10 and amplified. At this time, the pumping light from the pumping light source 17 is also input to the optical fiber 10 through the wavelength synthesizer 15 on the rear side, and the pumping light is bidirectionally pumped. The amplified signal light is separated from the pumping light by the wavelength synthesizer 15, and further passed through the isolator 16 and sent out from the output terminal OUT1. Therefore, even if one of the pumping light sources 13P17 provided on the front side and the backside of the optical fiber 10 fails and the pumping light cannot be input to the optical fiber 10, the other pumping light source The pumping light can be input to the optical fiber, and the optical amplification function can be secured. This is exactly the same for the downlink.

[0005]

In this conventional bidirectional pumping optical amplifier, pumping light sources are required on the front side and the rear side of one optical fiber, so that the uplink and downlink shown in FIG. 3 are required. In a signal transmission line in which lines are arranged in parallel, four pump light sources are required as the signal transmission line. Therefore, the space for arranging the pumping light source becomes large, which hinders the miniaturization of the amplifier, and the scale of the laser driving circuit for driving the pumping light source becomes large, which causes a problem that the current consumption increases. . An object of the present invention is to provide a bidirectional pumping optical amplifier capable of reducing the number of pumping light sources, downsizing the amplifier, and reducing current consumption.

[0006]

In the bidirectional pumping optical amplifier of the present invention, a wavelength synthesizer is provided in the front and rear sides of each of the upstream and downstream lines with an optical fiber in between, and each of
Only the pumping light source is provided, and the pumping light from each pumping light source is configured to be input to only one of the wavelength synthesizers on the front side or the rear side of the own line, and the other wavelength synthesizer. The pumping light from the pumping light source of the other line is input through the optical fiber of the other line and the wavelength synthesizers on the front side and the rear side thereof. For example, the pumping light from each of the upstream and downstream pumping light sources is configured to be input only to the wavelength synthesizer on the front side of the own line, and the pumping light from the pumping light sources of other lines is configured on the rear side wavelength synthesizer. Excitation light is in front of the other line
It is configured to be input via a wavelength synthesizer, an optical fiber, and a wavelength synthesizer on the rear side . Alternatively, the pumping light from each of the upstream and downstream pumping light sources is configured to be input only to the wavelength synthesizer on the rear side of the own line, and the wavelength synthesizer on the front side receives the pumping light from the pumping light sources of other lines. Excitation light is after another line
Side wavelength synthesizer, optical fiber and rear side wavelength synthesizer
To be input.

[0007]

Next, the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of the first embodiment of the present invention. In the figure, an upstream line 1 is used as an optical cable for transmitting signal light.
00 and a downlink 200 are arranged in parallel, and each optical cable has an erbium-doped optical fiber (EDF: hereinafter simply referred to as an optical fiber) 10, 2 for forming an optical amplifier.
0 is inserted. In the upstream line 100, an isolator 11 and a wavelength synthesizer 12 are inserted on the front side of the optical fiber 10, and a laser diode 13 as a pumping light source is connected to the wavelength synthesizer 12 via an isolator 14. A wavelength synthesizer 15 and an isolator 16 are also provided on the rear side of the optical fiber 10.
A laser diode as an excitation light source is not connected to 5 and the wavelength synthesizer 2 on the rear side of the downlink 200 described later is used.
Connected to 5. On the other hand, also in the downlink 200, the isolator 21 and the wavelength synthesizer 2 are provided in front of the optical fiber 20.
A laser diode 23 as an excitation light source is connected to the wavelength synthesizer 22 via an isolator 24. Further, a wavelength synthesizer 25 and an isolator 26 are also inserted on the rear side of the optical fiber 20, but a laser diode as an excitation light source is not connected to this wavelength synthesizer 25, and the wavelength of the optical fiber 20 is increased after the upstream line 100. It is connected to the wavelength synthesizer 15 on the side.

The operation of the optical amplifier having this configuration will be described. In the upstream line 100, the signal light input from the input end IN1 is transmitted from the pumping light source 13 of the own line in the front side wavelength synthesizer 12.
Is combined with the pumping light from and input to the optical fiber 10,
The optical fiber 10 absorbs the excitation light and amplifies the signal light. The amplified signal light is separated from the pumping light by the wavelength combiner 15 on the rear side, and further passes through the isolator 16 and is output from the output end OUT1. In addition, the separated pumping light is used for the downlink 20.
It is input to the wavelength synthesizer 25 on the rear side of 0. On the other hand, in the downlink 200, the signal light input from the input terminal IN2 is combined with the pump light from the pump light source 23 of the own line in the front side wavelength combiner 22 and is input to the optical fiber 20, and the optical fiber 20 is pumped. It absorbs light and amplifies signal light. The amplified signal light is separated from the pumping light by the wavelength combiner 25 on the rear side, and further transmitted through the isolator 26 from the output end. The separated pumping light is input to the wavelength combiner 15 on the rear side of the upstream line 100.

Therefore, in the optical fiber 10 of the upstream line 100, the optical fiber 10 of the upstream line 100 is pumped from the front by the pumping light from the own pumping light source 13 that has passed through the wavelength combiner 12 on the front side, and at the same time, the pumping light source 23 of the downstream line 200. Pumping light from the optical fiber 20, the wavelength synthesizer 25 on the rear side of the downlink,
Since the light is input from the rear side through the wavelength combiner 15 on the rear side of the uplink, it is excited in both directions. Similarly, in the optical fiber 20 of the downlink 200, the pump light from the pump light source 23 of the own line that has passed through the wavelength combiner 22 on the front side is pumped from the front, and at the same time, the pump light source 13 of the uplink 100 is pumped. The pumping light is the optical fiber 10, the wavelength combiner 15 on the rear side of the uplink, and the wavelength combiner 25 on the rear side of the downlink.
It is input from the rear through and is excited in both directions.

As a result, both the upstream and downstream optical fibers 10 and 20 are bidirectionally pumped, and even if a failure occurs in the pumping light source 13 of the upstream 100, the downstream 200 Pumped from the pumping light source 23 of the
The downlink 200 is excited from the front side, and the amplification of the signal light by the optical fibers 10 and 20 is secured in each line. Further, even if a failure occurs in the pumping light source 23 of the downlink 200, the pumping light source 13 of the uplink 100 pumps the uplink 100 from the front side and the downlink 2
At 00, excitation is performed from the rear, and each amplification is secured. Therefore, 2 for both uplink and downlink
Only one pumping light source 13 and 23 is required, the number of pumping light sources can be reduced, the installation space can be reduced, the amplifier can be downsized, and the current consumption can be reduced.

2 is a block diagram of a second embodiment of the present invention,
The same parts as those in FIG. 1 are designated by the same reference numerals. This embodiment is the same as the first embodiment in that the isolators 11 and 16 and the wavelength synthesizers 12 and 15 are inserted on the front side and the rear side of the optical fiber 10 in the upstream line 100, respectively. A laser diode 17 as an excitation light source is connected to the wavelength synthesizer 15 through an isolator 18, and a laser diode as an excitation light source is not connected to the wavelength synthesizer 12 on the front side. It is connected to the wavelength synthesizer 22. On the other hand, downlink 1
In No. 00, the wavelength synthesizers 22 and 25 and the isolators 21 and 26 are inserted on the front side and the rear side of the optical fiber 20, respectively.
The pumping light source 27 is connected via 8 and the wavelength synthesizer 2 on the front side is connected.
No pumping light source is connected to 2 and the uplink 10
It is connected to the wavelength synthesizer 12 on the front side of 0.

The operation of the optical amplifier having this configuration will be described. In the upstream line 100, the signal light input from the input terminal IN1 is input to the optical fiber 10 through the front side wavelength combiner 12, and at this time, the pumping light source connected to the rear side wavelength combiner 25 of the downstream line 200. Since the pumping light from 27 is input to the wavelength combiner 12 on the front side of the optical fiber 20 and the wavelength combiner 22 on the front side of the downlink, the signal light is combined with the pumping light and input to the optical fiber 10. It Thereby, the optical fiber 10 absorbs the pumping light and amplifies the signal light. The amplified signal light is separated from the pumping light by the wavelength combiner 15 on the rear side, and further passes through the isolator 16 and is output from the output end OUT1. At this time, the pumping light from the pumping light source 17 of the uplink 100 is input to the optical fiber 10 through the wavelength combiner 15 on the rear side, so that the optical fiber 10
Will also be excited from behind by this. Further, the pumping light from the rear passes through the optical fiber 10, further passes through the front side wavelength synthesizer 12, and is input to the front side wavelength synthesizer 22 of the downlink 200.

On the other hand, in the downlink 200, the input terminal IN2
The signal light input from the front side wavelength combiner 22 is combined with the pumping light from the pumping light source 17 of the upstream line 100 and input to the optical fiber 20, and the optical fiber 20 absorbs the pumping light and amplifies the signal light. To do. The amplified signal light is separated from the pumping light by the wavelength combiner 25 on the rear side, and further passes through the isolator 26 and is output from the output end OUT2. At this time, the pumping light from the pumping light source 27 of the downlink 200 is input to the optical fiber 20 through the wavelength synthesizer 25 on the rear side, and the optical fiber 20 is pumped from the rear. Further, the pumping light passes through the optical fiber 20, and further is input to the wavelength combiner 12 on the front side of the uplink 100 through the wavelength combiner 22 on the front side, and is combined with the signal light on the uplink as described above.

Therefore, in the optical fiber 10 of the upstream line 100, the pumping light from the pumping light source 17 of the own line is pumped from the rear, and at the same time, the pumping light from the pumping light source 27 of the downstream line 200 is sent to the optical fiber 20. , The signal is input from the rear through the wavelength synthesizer 22 on the front side of the downlink and the wavelength synthesizer 15 on the rear side of the own line, so that it is excited in both directions. Similarly, in the optical fiber 20 of the downlink 200, the pumping light from the pumping light source 27 of its own line is used to pump from the front, and at the same time, the pumping light source 1 of the uplink 100 is sent.
The pumping light from the optical fiber 7 is input from the rear through the optical fiber 10, the wavelength combiner 12 on the front side of the upstream line, and the wavelength combiner 25 on the rear side of the own line, and is excited bidirectionally.

Therefore, in this embodiment as well, both the upstream and downstream optical fibers are bidirectionally pumped, and even if a failure occurs in either the upstream or downstream pump light source. The amplification of each line is secured by the pump light source of the other line. As a result, it is only necessary to provide two pump light sources for both the uplink and the downlink, the number of pump light sources is reduced, the installation space is reduced, the amplifier is downsized, and the current consumption is reduced. be able to.

[0016]

The present invention described above, according to the present invention, respectively provided only one excitation light source to the uplink and downlink, own
The pumping light from the pumping light source of the line is
Input to the wavelength synthesizer, pumping light from pumping light source of other line
Is configured to be input to the optical fiber after being input to the wavelength synthesizer on the rear side or the front side . Therefore, bidirectional pumping is performed on the optical fibers provided on the uplink and the downlink, respectively. Even if one pumping light source fails, the other pumping light source can hold the pumping state to ensure the reliability of the amplifier, and each line has only one pumping light source. Therefore, as a result, it is sufficient to provide two pumping light sources on both lines, the number of pumping light sources can be reduced, the installation space can be reduced, the optical amplifier can be downsized, and the current consumption can be reduced. The effect is that you can do it.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a first embodiment of a bidirectional pumping optical amplifier of the present invention.

FIG. 2 is a configuration diagram of a second embodiment of a bidirectional pumping optical amplifier of the present invention.

FIG. 3 is a configuration diagram of an example of a conventional bidirectional pumping optical amplifier.

[Explanation of symbols]

 10,20 Optical fiber (EDF) 12,22 Front side wavelength synthesizer 13,23 Excitation light source 15,25 Rear side wavelength synthesizer 17,27 Excitation light source 100 Uplink 200 Downlink

Claims (3)

(57) [Claims] 1. An optical fiber in which an upstream line and a downstream line for transmitting signal light are arranged in parallel, and an optical fiber doped with a rare earth element or the like is provided in each line, and the optical fiber is provided in front of and behind this optical fiber, respectively. Bidirectional pump configured to combine or separate the signal light and the pump light by the wavelength synthesizer, and the wavelength synthesizer and a pumping light source that generates pumping light for pumping the optical fiber. In the optical amplifier, each line is provided with only one pumping light source, and the pumping light from each pumping light source is input only to either the front side or the back side of the own line. Pumping from the pumping light source of the other line to the other wavelength synthesizer.
Light is the optical fiber of the other line and each wavelength synthesis before and after it
A bidirectional pumping optical amplifier characterized in that it is configured to be input via a pump. Wherein the uplink and the pumping light from the pumping light source of the downlink is configured to be inputted only to the front side of the wavelength multiplexing device of each own line, the wavelength combiner of the rear of another line commutated
The excitation light from the source is the wavelength synthesizer and optical
2. The bidirectional pumping optical amplifier according to claim 1, wherein the bidirectional pumping optical amplifier is configured to be input via a fiber and a wavelength synthesizer on the rear side . 3. The pumping light from each of the pumping light sources of the up-link and the down-link is configured to be input only to the wavelength combiner on the rear side of the own line, and the pumping lights of other lines are excited on the front side wavelength combiner.
The excitation light from the source is the wavelength combiner and optical
2. The bidirectional pumping optical amplifier according to claim 1, wherein the bidirectional pumping optical amplifier is configured to be input via a fiber and a front side wavelength synthesizer .