JPH04253037A - Multifiber optical amplifier and structure for connecting multiple optical fiber using this amplifier - Google Patents

Abstract

PURPOSE:To allow the simultaneous amplification of the signal light transmitted in plural optical fibers by disposing plural pieces of the rare earth-added optical fibers in a closed region having an inside surface of a high reflectivity and making exciting light incident on a part of the closed region. CONSTITUTION:This optical amplifier 10 has a glass block 11 formed with a metallic reflection layer on the surface, plural pieces of the rare earth-added optical fibers 12 embedded therein and a exciting light source 13 disposed in the body 11 in such a manner that the exciting light can be made incident on the inside thereof. The reflectivity between both is set at least at >=90%. The light entering from the exciting light source 13 makes multiple reflection within the closed region and the rare earth ions included in the core of the optical fibers absorb light during this time attains a excited state, by which the inversion distribution is formed. The signal light is amplified by induced radiation if this signal light propagates in the core. The optical amplification of all the plural optical fibers is thus executed.

Description

[Detailed description of the invention]

0001

[Industrial Application Field] The present invention relates to an amplifier for amplifying signal light transmitted within an optical fiber using a rare earth-doped optical fiber, and in particular to a multi-fiber optical amplifier capable of amplifying multi-core optical fibers. Regarding structure.

0002

2. Description of the Related Art Direct amplification of light using rare earth-doped optical fibers is an optical fiber technology that has recently attracted attention. FIG. 6 shows an example of this amplification technology. The excitation light from the excitation light source 3 is input into the doped single mode fiber using the optical coupler 2. This causes population inversion in the energy of erbium ions, similar to a normal laser. In this state, when the signal light 4 enters the rare earth-doped optical fiber 1 through the optical coupler 2, the energy of the erbium ions excited by the excitation light is given to the signal light by stimulated emission, and the amplified light is transmitted to the fiber communication path. The configuration is such that the data is transmitted to 5.

0003

[Problem to be Solved by the Invention] However, in conventional amplifiers, it is necessary to provide an optical amplifier for each fiber, and in order to support multiple optical fibers, it is necessary to prepare many optical amplifiers. was there. Since this optical amplifier is quite expensive, connecting an optical amplifier to each fiber of a multi-core optical fiber will increase the cost of the optical communication system. Furthermore, in multi-fiber cables and the like, connecting such an optical amplifier to each fiber requires a large installation space, which is impractical.

The present invention has been made in view of the above circumstances, and is a compact and simple-structured multi-fiber optical amplifier that simultaneously amplifies light in multi-core optical fibers. It is an object of the present invention to provide an optical amplifier that is suitably applied in the field of optical communications that does not require amplification.

[0005]

[Means for solving the problem] This problem is solved by arranging a plurality of rare earth-doped optical fibers in a closed region having an inner surface with high light reflectance, and providing an opening in a part of the closed region to excite the optical fibers. This problem can be solved by introducing light or by arranging an excitation light source in a closed area to excite the optical fiber from the side.

The rare earth-doped optical fiber preferably contains at least one rare earth element selected from erbium, neodymium, and ytterbium in the core of the optical fiber. Further, the closed region with high light reflectance can be formed by surrounding a high refractive index glass region with a low refractive index glass region. Further, the multi-fiber optical amplifier described above can be incorporated in the middle of a multi-core optical fiber transmission line to configure a multi-core optical fiber connection structure.

[0007]

[Operation] The optical amplifier according to the present invention arranges a plurality of rare earth-doped optical fibers in a substantially closed area, and injects light from an excitation light source into this closed area, so that the light is multiplexed within the closed area. During the reflection, the rare earth ions contained in the core of the optical fiber absorb the light and become excited, forming a population inversion. When the signal light propagates through the core, the signal light is amplified by stimulated radiation. Therefore, it is possible to perform optical amplification of all the plurality of optical fibers arranged within the closed area.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIGS. 1 and 2 show an embodiment of an optical amplifier according to the present invention. This optical amplifier 10 includes a glass block 11 with a metal reflective layer formed on its surface, a plurality of rare earth-doped optical fibers 12 embedded inside the glass block 11, and a structure arranged so that excitation light can enter the main body 11. and an excitation light source 13.

The glass block 11 is composed of a plate-shaped or prismatic glass body 11a and a metal reflective layer 11b formed on the outer surface of the glass body 11a. The metal reflective layer 11b is formed by vapor-depositing aluminum or silver or electroless plating nickel or the like on the main body 11a. The reflectance between the glass main body 11a and the metal reflective layer 11b is at least 90% or more.

The rare earth-doped optical fiber 12 is composed of a core 14 and a cladding 15 surrounding the core 14, as shown in FIG. The cladding 15 is made of pure quartz, and the core 14 is made of quartz containing at least one rare earth element selected from erbium, neodymium, and ytterbium. The amount of rare earth elements added is 1 in the core material.
It is desirable to set it to about 000-4000 ppm. When an excitation light source enters the rare earth element-doped optical fiber 12 from the outside of the fiber, the rare earth ions in the core 14 absorb the light and become excited, forming a population inversion. When the signal light propagates through the core, it is amplified.

[0011] At both ends of this rare earth-doped optical fiber 12, normal optical fibers 16 not doped with rare earth are fusion spliced (in FIG. 2, reference numeral 16b indicates a fusion splice portion). ). These optical fibers 16 are made by inserting a rare earth-doped optical fiber between the optical fibers to be connected and fusion splicing them at a continuation point of a multi-fiber line such as an optical cable having a plurality of optical communication fibers. It constitutes a multi-fiber line.

The excitation light source 13 is a glass block 11
Excitation light is made to enter the glass block 11 from a light source 13 such as a laser light source provided outside the glass block 11 through a light guide 17. A diffusion lens 18 is provided at the connection between the tip of the light guide 17 and the glass block 11 to prevent the excitation light from concentrating too much in a specific direction and irradiating a specific fiber.

In the optical amplifier 10, when excitation light is input from the excitation light source 13 into the main body 11a of the glass block 11, this light undergoes multiple reflections within the main body 11a. During this time, the excitation light is gradually absorbed by the rare earth ions contained in the core 14 of the rare earth doped optical fiber. As a result, the rare earth ions in the core 14 become excited and a population inversion is formed. When the signal light propagates through the core 14, it is amplified.

Therefore, by using this optical amplifier 10, optical amplification in a multi-fiber line having a plurality of optical fibers can be performed simultaneously by one device, and the optical amplification system in the multi-fiber line can be miniaturized and simplified. This makes it possible to construct an optical amplification system on a multi-fiber line.

It can also be applied to the field of optical communications that does not necessarily require high output and high gain amplification. For example, by applying this optical amplifier 10 to a multi-core connector of a multi-fiber, connection loss can be reduced. It is possible to form a connector with no or some amplification effect.

In the above embodiments, the shape of the glass block is flat or prismatic, but the shape is not limited to this, and it is also possible to form it in a cylindrical shape, a polygonal column, or the like.

[0017]Although plastic or organic material may be used instead of the glass block, it is necessary to use a material with low attenuation of light. By the way, silicone materials cost several thousand to tens of thousands of d.
B/km per 10 cm is on the order of 0.1 to several dB.

FIG. 4 shows another embodiment of the optical amplifier according to the present invention, in which reference numeral 20 is an optical amplifier. This optical amplifier 20 connects a multi-fiber line in which a plurality of optical fibers 16 are bundled with a rare earth-doped optical fiber 12 interposed therebetween.
2 is embedded in a cylindrical glass block 21, and a low refractive index glass layer 22 made of glass having a lower refractive index than the material of the glass block 21 is further formed on the glass block 21. As the material for the low refractive index glass layer 22, when the glass block 21 is made of quartz, fluorine-doped quartz is suitably used.

In this optical amplifier 20, total reflection of light occurs at the interface between the glass block 21 and the low refractive index glass layer 22, so that the excitation light incident on the glass block 21 does not leak outside. It is possible to advance the excitation light.

FIG. 5 also shows the optical amplifier 1 of each of the above-mentioned embodiments.
0,20 is a diagram showing an application example of optical amplifiers 10,2.
A multi-core connector 2 is attached to each fiber bundle extending to both ends of 0.
3 can be connected to form a lossless connector element that can be easily connected to the multi-core connector 25 formed at the end of the multi-fiber 24.

(Experimental Example) Sixteen optical fibers were arranged in parallel on a plane. These 16 fibers are approximately 20
Single-mode optical fibers were fusion-spliced to both ends of a 0 mm erbium-doped optical fiber, and the rare earth-doped optical fiber portions of these fibers were also embedded in a glass block as shown in FIG. 1. A vapor deposited aluminum film (metallic reflective film) was formed on the surface of this glass block except for a part, and the reflectance of the glass block and the surface of the vapor deposited film was ensured to be 90% or more. Inside this block is a pumping light with a wavelength of 1.48μm (high output laser, output approximately 40μm).
0 mW) was incident. At this time, the laser emitting end face may be directly connected to the block end, but in this experimental example, the distance is 100 m.
Polarization-multiplexed light using four lasers with an output of W was guided through an optical fiber, and the light was irradiated into the glass block. In addition, a cylindrical lens was placed at the laser output end to prevent the light from concentrating too much in a specific direction so that only specific fiber sections were strongly excited, while not leaving unexcited portions.

[0022] The rare earth-doped optical fiber used here is
A core containing approximately 3000 ppm of erbium ions was used. The parameters of this rare earth doped optical fiber are: fiber outer diameter of 125 μm, core diameter of 8 μm, refractive index difference between core and cladding of approximately 0.42%, cutoff wavelength of 1.3 μm, and signal light wavelength of 1.55 μm. The wavelength of the excitation light was 1.47 to 1.49 μm.

[0023] Also, the glass block has a length of 220 mm,
The width was 10 mm and the thickness was 6 mm. In this example, the glass block length was set to be long to match the rare earth doped optical fiber having a length of about 200 mm, but if a fiber with high efficiency and a high erbium doping concentration can be used, the glass block length can be shortened. In addition, the irradiation angle of the laser beam (excitation light) into the glass block is 5° x 30° due to the diffusion lens.
It was made oblate.

Using this device, the amplification of the fiber finally obtained was 1.3 dB on average, 0.5 dB at minimum, and 1 dB at maximum.
．． It was 8dB. Although this amplification is a so-called small signal characteristic, it is larger than the losses often experienced at optical fiber connections, and has a value that can compensate for these connection losses.

[0025]

As explained above, according to the optical amplifier of the present invention, optical amplification in a multi-fiber line having a plurality of optical fibers can be performed simultaneously by one device. The system can be miniaturized and simplified, and an optical amplification system can be constructed on a multi-fiber line. It can also be applied to the field of optical communication that does not necessarily require high output and high gain amplification. For example, by applying this optical amplifier 10 to a multi-fiber connector section, it is possible to check whether there is any connection loss or not. It is possible to form a connector with some amplification effect.

[Brief explanation of the drawing]

FIG. 1 is a perspective view showing an embodiment of a multi-fiber optical amplifier of the present invention.

FIG. 2 is a plan cross-sectional view of the multi-fiber optical amplifier.

FIG. 3 is a diagram showing an end face of a rare earth-doped optical fiber preferably used in the present invention.

FIG. 4 is a perspective view showing another embodiment of the multi-fiber optical amplifier of the present invention.

FIG. 5 is a side view for explaining an application example of the multi-fiber optical amplifier of the present invention.

FIG. 6 is a configuration diagram for explaining a conventional optical amplifier.

[Explanation of symbols]

10, 20 Optical amplifier 11, 21 Glass block 12 Rare earth doped optical fiber 13 Excitation light source

Claims (3)

[Claims] Claim 1: A plurality of rare earth-doped optical fibers are arranged in a closed region having an inner surface with high light reflectance, and
A multi-fiber optical amplifier characterized in that the optical fiber is pumped from the side by providing an opening in a part of the closed area to allow pumping light to enter or by placing a pumping light source in the closed area. 2. The multi-fiber optical amplifier according to claim 1, wherein the closed region with high light reflectance is formed by surrounding a high refractive index glass region with a low refractive index glass region. 3. A multi-core optical fiber connection structure, characterized in that the multi-fiber optical amplifier according to claim 1 or 2 is incorporated in the middle of a transmission path.