JPS62275203A - Fixed attenuator for single mode fiber - Google Patents

Abstract

PURPOSE:To stably attenuate signal light by connecting a single mode filter which has a different mode field diameter and whose core diameter is equal to the external diameter of an intermediate layer to a W type optical fiber which has the intermediate layer having a smaller refractive index than a clad part. CONSTITUTION:The W type optical fiber 1 has the intermediate layer 13 having the smaller refractive index than the clad part 12 between a core part 11 and the clad part 12. An optical fiber 2 which has a core 21 whose diameter is equal to the external diameter of the intermediate layer 12 and also has the mold filed diameter different from the mold field diameter of the W type fiber 1 is connected to one terminal of the W type fiber 1. An optical fiber 3 which has a core 31 whose diameter equal to the external diameter of the intermediate layer 13 and also has a mold field diameter different from the mold field diameter of the W type fiber 1 is connected to the other terminal of the W type optical fiber 1. Consequently, signal light can be attenuated stably by the simple constitution.

Description

[Detailed Description of the Invention] 3. Detailed Description of the Invention Summary W comprising an intermediate layer having a smaller refractive index than the cladding part
A single-mode fiber having a mode field diameter different from that of the W-type optical fiber and having a core diameter the same as the outer diameter of the intermediate layer of the W-type optical fiber is added to the W-type optical fiber. By configuring the connection to match the layers and passing the signal light through this connection, it is possible to stably attenuate the signal light with a simple configuration.

INDUSTRIAL APPLICATION FIELD The present invention relates to a fixed attenuator for single mode fiber that attenuates input signal light at a predetermined attenuation rate. This invention relates to a fixed attenuator for single mode fiber.

In an optical communication system using an optical fiber as a signal transmission path, it may be necessary to attenuate transmitted signal light to an optimal level depending on the photoelectric characteristics of a light receiving section. In such cases, the optical fiber is usually connected to the light receiving section via a suitable fixed attenuator.

On the other hand, as transmission capacity increases and relay spans become longer distances, single-mode fiber, which has an inherently wide band, has come into use in recent years. Since the diameter is small and precision is required for mechanical connection, there is a need for a fixed attenuator for single mode fibers that can obtain a desired attenuation factor with a simple configuration.

BACKGROUND OF THE INVENTION Some of the methods that have been proposed or put into practical use as methods to obtain a predetermined attenuation factor by connecting to a single mode fiber are shown below.

(1) A spacer is interposed at the end of the fiber, that is, at the connection part with the light receiving part.

(2) An attenuator such as a filter is provided at the ends of the fibers or at the butt portions of the fibers.

(3) Forming a constriction in the middle of the fiber.

(4) Forming a bend in the middle of the fiber.

(5) Interpose another fiber with a larger core diameter in the middle of the fiber.

Problems to be Solved by the Invention Among the above-mentioned conventional techniques, method (1) has a practical problem because it is difficult to control the attenuation rate with high precision.

In method (2), it is necessary to provide a condensing lens, etc., resulting in a complicated configuration.

In the methods (3) and (4), problems in strength arise when attempting to obtain a practical attenuation rate.

Method (5) is noteworthy in that it utilizes the attenuation of signal light caused by connecting fibers with different mode field diameters. Another problem is that propagation of a new Rad mode with unstable leakage occurs in a fiber with a small core diameter, making it impossible to obtain stable attenuation.

The present invention was created in view of these problems, and an object of the present invention is to provide a fixed attenuator for single mode fiber that can obtain stable attenuation with a simple configuration.

Means for Solving the Problems FIG. 1 is a diagram illustrating the principle of a fixed attenuator for a single mode fiber according to the present invention.

In the figure, reference numeral 1 denotes a W-type optical fiber having an intermediate layer 13 having a refractive index smaller than the refractive index of the cladding part 12 between the core part 11 and the cladding part 12.

An optical fiber 2 having a core 21 with a diameter equal to the outer diameter of the intermediate layer 13 and a mode field diameter different from that of the W-type fiber 1 is connected to one end of the W-type optical fiber 1. .

At the other end of the W-type optical fiber 1, like the one end, there is an optical fiber having a core 31 with a diameter equal to the outer diameter of the intermediate layer 13 and a mode field diameter different from that of the W-type fiber 1. 3 is connected.

Note that the magnitude relationship between the mode field diameters of the optical fibers 2 and 3 is not particularly limited.

Function Generally, the radial optical power distribution in the transmission mode of a single mode fiber is approximately a Gaussian distribution, and the diameter at which the optical power is 1/e2 of the peak value is called the mode field diameter.

When fibers with different mode field diameters are connected, signal light passing through these interfaces is attenuated by a predetermined amount of attenuation determined according to the difference in mode field diameter.

The attenuation fitD in this case is expressed as B, where the mode field diameters of the respective fibers are ω and ω'.

Therefore, when a transmission line made of a single mode fiber is connected to both ends of the fixed attenuator of the present invention using an appropriate connection means such as an optical connector, the signal light propagated through the transmission line will be transmitted between the transmission line and the optical fiber. 2 interface, optical fiber 2 and W
Boundary surface of type fiber 1, W type fiber 1 and optical fiber 3
The signal is attenuated at a predetermined ratio at the interface between the optical fiber 3 and the transmission line, and is output.

As a result, it becomes possible to stably attenuate signal light with a simple configuration.

Friend-1-1 A fixed attenuator for a single motor fiber having the structure shown in FIG. 1 can be manufactured, for example, as follows.

In the manufacturing process of the W-type fiber 1, first, a silica glass layer doped with germanium oxide or phosphorus pentoxide, which will become the cladding part 12, is deposited on the inner surface of a pure quartz tube by internal CVD. Next, on the inner surface, there is a middle layer 1.
3. Deposit fluorine-doped silica glass. Finally, a preform is created by depositing silica glass doped with germanium oxide ■v, which will become the core part 11. After drawing in the usual manner, the W-shaped fiber 1 is cut into a predetermined length. can get.

On the other hand, the optical fibers 2 and 3 are obtained by drawing a preform made by a normal silica fiber manufacturing method, for example, the above-mentioned inner material CVD method, and then cutting the preform into a predetermined length.

These optical fibers 2.3 and the W-type fiber 1 are connected, for example, by a normal fusion method so that the outer diameters of the cores 21 and 31 and the outer diameter of the intermediate layer 13 match at their end faces. Therefore, the end face of the core portion 11 is included in the end faces of the cores 21 and 31, and the end faces of the cladding portions of each fiber are coincident. Therefore, unstable leakage and Rad mode propagation are less likely to occur, and a stable amount of attenuation can be obtained.

2(a), (b), and (c) show the refractive index distributions of the optical fiber 2, the W-type fiber 1, and the optical fiber 3, respectively. The outer diameter a of the core and intermediate layer of each fiber is 8.7 μm, and the core part 1 of the W-type fiber 1
The diameter of No. 1 was 2.0 μm or less. The relative refractive index difference Δ2 of the core 21 in the optical fiber 2, the relative refractive index difference Δ1 of the intermediate layer 13 in the W-type fiber 1, and the relative refractive index difference Δ3 of the core 31 in the optical fiber 3 satisfy the following formula. be.

6250.2% Δ1≧2.0% 6350.2% Each of the above-mentioned fiber parameters is determined as appropriate according to each mode field diameter and single mode transmission conditions of each fiber to obtain the desired attenuation rate. The parameters can be controlled by "adjusting" the doping of each fiber component.

The attenuation factor of the fixed attenuator configured in this way is calculated as follows. Now, optical fiber 2, W type fiber 1
, and each mode field diameter ω, ω1 of the optical fiber 3
, and ω3 are assumed to be ω2-14 μm ω1-3 μm ω3-14 μm according to the above-mentioned individual variables and 2 meters. For example, when a single mode fiber with a mode field diameter ω0 of 10 μm is connected to both ends of this fixed attenuator, the total amount of attenuation Dt is calculated according to the formula shown in the operation section of the detailed description of the invention. (2ω ω /(ω0 +ω2 ))+
ω ))-201oo(2ω2ω1/(ω21 −2010(+(2ω1ω3/(ω13+ω))) B, and by substituting each numerical value into this equation, Dt” becomes 16.5 dB.

In this way, in this example, each fiber parameter was set so that the difference in mode field diameter was relatively large, so that a sufficiently practical attenuation factor could be obtained.

Effects of the Invention As described above, the present invention has the effect of making it possible to stably obtain a sufficiently practical attenuation factor with an extremely simple configuration.

[Brief explanation of the drawing]

Fig. 1 is a diagram explaining the principle of the fixed attenuator for single mode fiber of the present invention, Fig. 2(a), Fig. 2(b), and Fig. 2(C) show the refractive index distribution of each fiber. FIG. 1... W-type fiber, 2.3... Optical fiber,
11...W type fu? 12... Cladding part of W-type fiber, 13... Intermediate layer of W-type fiber, 21.31... Core of optical fiber.

Claims (1)

[Claims] An intermediate layer (1) having a refractive index smaller than the refractive index of the cladding part (12) is formed between the core part (11) and the cladding part (12).
3) a W-type optical fiber (1) with an intermediate layer (13)
W-type optical fiber (1) having a core diameter equal to the outer diameter of
The core of the optical fibers (2) and (3) and the W-type optical fiber (
The optical fiber (
A fixed attenuator for a single mode fiber, characterized in that 2) and (3) are connected to both end faces of a W-type optical fiber (1).