JPH022508A - Optical attenuator - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [(Already required)] This invention relates to optical attenuators, particularly variable optical attenuators, which can be switched by remote control by turning on and off electrical signals, is easy to operate, and is compact. multiple optical fibers arranged in series for optical coupling,
In order to apply a magnetic field to the rare earth iron garnet thin film inserted and disposed between the input end face and the output end face of each optical fiber, and to apply a magnetic field to the selected rare earth iron garnet thin film, The optical power output from the output side optical fiber is made variable by selecting the number of rare earth iron garnet thin films to which a magnetic field is applied.

[Industrial application field]

The present invention relates to an optical attenuator, and particularly to a variable optical attenuator.

When transmitting and receiving optical signals between distant locations using optical fibers, the optical signal transmitted with sufficiently strong optical power on the transmitting side is reduced to a predetermined optical power using an optical attenuator on the receiving side. Generally, it is received by

The optical attenuator used in this manner is preferably a so-called variable type optical attenuator that can adjust the amount of reduction as desired depending on the length of the distance between the two sides.

[Conventional technology]

(al and (bl) in FIG. 4 are the configuration diagrams of the conventional example.

As shown in FIG. 4(a), the conventional optical attenuator has an attenuation film 6 formed on the disk surface between the input optical fiber 1 and the output optical fiber 3, and is rotatable manually. damping disk 5
This is an optical attenuator with an inserted.

Note that a lens 4 is installed near the output end face of the input optical fiber 1.
is arranged so that the light emitted from the input end optical fiber 1 is made into a parallel beam and projected perpendicularly to the attenuation film 6 of the attenuation disk 5.

Further, another lens 4 is disposed near the input end face of the output side optical fiber 3 so that the parallel beam transmitted through the attenuation film 6 is focused on the input end face.

The attenuation disk 5 has a disk shape made of optical glass, and a pin 7 is inserted into the center hole, and the attenuation disk 5 can be rotated manually by pivoting the pin 7.

A metal 1, such as titanium, is deposited on the disk surface of the damping disk 5 to form a damping film having a desired thickness. To be more specific, as shown in FIG. 4(b), the disk surface of the damping disk 5 is equally divided into fan shapes, and each section is provided with a damping film 6 having a different thickness.
-1, 6-2, 6-3, . . . are arranged in descending order of film thickness to constitute the damping model 6.

Since the configuration is as described above, the light emitted from the input end optical fiber 1 is incident on the attenuation disk 5, and is, for example, attenuated by the attenuation film 6.
-1, a desired amount of light is reflected and scattered, and the remainder passes through the attenuation disk 5 and enters the output optical fiber 3.

Furthermore, when the attenuation disk 5 is rotated to position the attenuation film 6-2 on the optical axis of the input side optical fiber 1, the amount of attenuation becomes smaller than that of the attenuation film 6-1, and the attenuation film 6-2 is positioned on the optical axis of the input optical fiber 1. Optical power that is stepwise stronger than in case 1 enters the output optical fiber 3.

That is, the optical attenuator described above is a manually variable optical attenuator.

[Problem to be solved by the invention]

However, in order to adjust the output optical power as desired using the above-mentioned conventional optical attenuator, the attenuation film must be manually attenuated so that the desired attenuation film is located at a position corresponding to the output end face of the input optical fiber. There is a problem in that the disc must be rotated and the damping disc must be engaged at that position to prevent rotation, making variable operation cumbersome.

Furthermore, since the attenuation disk can be operated manually, there is a problem in that the optical attenuator is relatively large.

The present invention was created in view of these points, and aims to provide a small variable optical attenuator that is easy to operate and can be switched by remote control by turning on and off electrical signals. There is.

[Means to solve the problem]

In order to achieve the above object, the present invention, as shown in FIG. , input side optical fiber 1. The optical fibers 2-1, 2-2, . . . and the output optical fiber 3 of a desired length are arranged in series so as to be optically coupled.

The rare earth iron garnet thin films 10 arranged in respective places are located at the center of the coil, and the thin films 10 of rare earth iron garnet are arranged in locations corresponding to the respective rare earth iron garnet thin films 10 so that a magnetic field is applied to the rare earth iron garnet thin films 10 when energized. An electromagnetic coil 15 is provided. Then, the number of rare earth iron garnet thin films 10 that apply a magnetic field is selected, and the output side optical fiber 3 is
The configuration is such that the optical power output from the optical power source can be adjusted as desired.

[Effect]

As shown in Figure 2 (al), rare earth iron garnet thin film 1
When no magnetic field is applied, countless fine striped magnetic domains 11 are generated in the rare earth iron garnet thin film 10. As a result, the light projected onto the rare earth iron garnet thin film 10 is emitted from the emission surface on the opposite side in a divergent manner due to the diffraction effect of the striped magnetic domains 11.

On the other hand, when a Kl field < the direction of the Gi'l field is shown by the arrow), the striped magnetic domain 11 disappears, and as shown in FIG.
As shown in 1), the parallel beam of light projected onto the rare earth iron garnet thin film 10 is
Pass through O2 and go straight.

As described above, if a magnetic field is not applied to the rare earth iron garnet a film 10, the light will be diffused, so the optical power incident on the optical fiber disposed in the next stage will be weakened, and it will have the function of an optical attenuator.

Therefore, by selecting a desired number of rare earth iron garnet thin films 10 and turning off the power to the corresponding electromagnetic coils 15, it is possible to emit optical signals with several levels of desired low optical power from the output optical fiber. can.

That is, the optical attenuator with the above configuration is a variable optical attenuator, and
The variable operation can be switched by turning on and off an electric signal, and the operation is extremely easy.

Furthermore, by installing the switch that drives the electromagnetic coil in a location separate from the optical attenuator, for example, on the operation panel of the optical device, the optical attenuator itself can be made smaller.

〔Example〕

The present invention will be specifically described below with reference to the drawings. Note that the same reference numerals indicate the same objects throughout the figures.

FIG. 3 is a block diagram of an embodiment of the present invention, in which input side optical fibers 1. The optical fibers 2-1, 2-2 and the output optical fiber 3 having a desired short length are arranged in series on a straight line in this order.

Then, the output surface of the input side optical fiber 2-
1. A lens 4 is installed facing each of the entrance surface of 2-2, the exit surface, and the entrance surface of the output side optical fiber 3,
Input side optical fiber 1. Optical fiber 2-1.2-2. The optical coupling efficiency between the output side optical fibers 3 is increased.

10 is a bismuth-substituted rare earth iron garnet thin film.

Between input side optical fiber 1 and optical fiber 2-1, between optical fiber 2-1 and optical fiber 2-2, and between optical fiber 2
-1 and the output side optical fiber 3, a rare earth iron IF+I is installed perpendicularly to the optical axis of the optical fiber.
A membrane 10 is provided.

Reference numeral 15 denotes an electromagnetic coil that is turned on and off by a switch (not shown).
Thin Jl! 10 is located at the center of the coil.

Therefore, when the electromagnetic coil 15 is energized, a perpendicular magnetic field can be applied to the rare earth iron garnet thin film 10.

When no magnetic field is applied to the rare earth iron garnet thin film 10, striped magnetic domains are generated in the rare earth iron garnet thin film 10, as described in detail in the section of the operation. Therefore, the parallel beam of light projected onto the rare earth iron garnet 1 film 10 is
From the output surface on the opposite side, the light is emitted with a wide spread toward the end, and the optical power entering the optical fiber disposed in the next stage becomes weaker.

When a 1J11 switch (not shown) is turned on to the electromagnetic coil 15, a magnetic field is applied and the stripe magnetic domain disappears. As a result, the parallel beam of light projected onto the rare earth iron garnet thin film 10 causes the rare earth iron garnet thin film IO to Pass through and go straight. When such a magnetic field is present, the light passing through the rare earth iron garnet thin film 10 has almost no decrease in optical power.

Therefore, in an optical attenuator in which three rare earth iron garnet thin films 10 are arranged as shown in FIG. 3, if one rare earth iron garnet thin film is designed to cause a loss of 5 dB, the electromagnetic coil By turning on and off 15, it is possible to create a three-stage variable optical attenuator with attenuation of 5 dB, 10 d[l, and 15 dB.

Note that the loss in each rare earth iron garnet thin film portion can be adjusted three times by changing the distance between the optical fibers.

Furthermore, by installing a switch that drives the electromagnetic coil in a location away from the optical attenuator, such as on the control panel of an optical device, remote control is possible.

The optical attenuator of the present invention is composed of an optical fiber, a small rare earth iron garnet thin film, and a small electromagnetic coil arranged so as to incorporate the rare earth iron garnet thin film, so that the optical attenuator itself can be miniaturized. is easy.

〔Effect of the invention〕

As explained above, the present invention is a variable optical attenuator using a rare earth iron garnet thin film, which is easy to operate because it can switch on and off of electrical signals, and can be easily miniaturized. It has excellent practical effects.

In the figure, 1 is an input side optical fiber, 2-1.2-2 is an optical fiber, 3 is an output side optical fiber, 4 is a lens, 5 is an attenuation disk, 6, 6-1.6-2.6- 3 is a damping film, IO is a rare earth iron garnet thin film, 11 is a striped magnetic domain, and 15 is an electromagnetic coil.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing the principle of the present invention, Figs. 2 (a) and (b) are diagrams explaining the present invention in detail, Fig. 3 is a block diagram of an embodiment of the present invention, and Fig. 4 (a) and (b) of the figure are diagrams of a conventional example. Kiyorou et al. 4 Raccoon and 11 shaku drawings 1. (cL) (b”) A drawing that suggests inferiority and the idea of ``IF#'l'' 2. Karine example of the group's invention Block diagram Figure 3 (b) Block diagram of 8 examples Figure 4

Claims (1)

[Claims] A plurality of optical fibers arranged in series for optical coupling, and a rare earth iron garnet thin film (10) inserted and disposed between the input end face and output end face of each of the optical fibers. In order to apply a magnetic field to the rare earth iron garnet thin film (10), each of the rare earth iron garnet thin films (10)
), the number of said rare earth iron garnet thin films (10) to be applied with a magnetic field is selected, and the optical power outputted from the output side optical fiber (3) is An optical attenuator characterized by being configured to be variable.