JP4020250B2 - Optical signal detection components - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical signal detection component having a monitoring function for detecting an optical signal inserted into an optical transmission line such as an optical fiber cable and transmitted through the optical transmission line.
[0002]
[Prior art]
Conventionally, a light detection device has been used to detect whether or not an optical signal is transmitted through an optical transmission line. This photodetection device is, for example, an optical branching device such as a half mirror that branches a part of a transmitted optical signal, an optical fiber that picks up an optical signal branched by this optical branching device, or an optical signal that is picked up by an optical fiber Is combined with a light emitting diode that displays an electric signal output from the photodiode as a visible signal, and the like.
[0003]
However, in the conventional photodetector, since a plurality of optical devices such as an optical branching device and a photodiode are combined, the number of devices is increased and a connector for connecting these devices is required. It was difficult.
Moreover, the optical branching device uses a half mirror or the like, and adjustment of such an optical system is time-consuming, and the manufacturing cost cannot be reduced.
[0004]
Further, as an invention according to the prior art for improving the drawbacks of the above-described photodetection device, for example, there is a photo relay device with a monitor function (Patent Document 1).
[0005]
[Patent Document 1]
Japanese Patent Laid-Open No. 2000-284152
The invention disclosed in Patent Document 1 will be described.
First, the angle of the end faces of the two optical fibers is formed to be 45 °, and a branch film that reflects a small amount of optical signals but transmits most of the optical signals is provided on the end faces. The branch film is formed by depositing a dielectric multilayer film or the like on a polyimide film, or by directly depositing a metal film or a dielectric multilayer film or the like on the polished surface of an optical fiber and a ferrule.
[0007]
Such two optical fibers are inserted into a transparent sleeve, the end faces are butted together, and are joined so that the end faces are in close contact with each other. In this way, the branch film is arranged in the optical fiber, and a small amount of the optical signal reflected by the branch film is detected so that the presence or absence of the optical signal on the transmission line can be determined.
[0008]
The photo relay device with a monitor function according to the prior art has to be manufactured by making use of precision processing such as forming the angle of the end face of the optical fiber at 45 °.
Further, if the end faces of the two optical fibers are not brought into close contact with each other, coupling loss occurs in the optical signal due to the deviation of the joint surfaces. In order to avoid such a situation, it has been necessary to manufacture the optical fiber while adjusting so that the end faces of the optical fiber are in close contact with each other.
These are all factors that increase the manufacturing cost, and it is difficult to reduce the manufacturing cost of the conventional photo relay device with a monitor function due to its structure.
[0009]
In view of such circumstances, the applicant of the present invention has proposed a fusion-type biconical taper coupler in which two optical fibers are arranged side by side and are substantially in close contact with each other and heated and fused while being stretched by applying tension from both sides. The invention relating to the optical signal detection component to be used has been invented and has been filed as Japanese Patent Application No. 2001-185260.
However, the fusion-type biconical taper coupler has a restriction that care must be taken not to make a mistake in the connection of the optical fiber, or care must be taken not to bend the optical fiber. There was a problem that the device had to be taken into consideration.
There is a need for further ease of manufacturing without these restrictions and for further miniaturization and cost reduction.
[0010]
[Problems to be solved by the invention]
The present invention has been made in order to solve the above-described problems, and an object of the present invention is to make it easy to manufacture without the restrictions required at the time of manufacturing, and to realize cost reduction and improvement in manufacturing workability. It is to provide a detection component.
[0011]
[Means for Solving the Problems]
According to the optical signal detection component of the invention according to claim 1 for solving the above problem,
A first transmission connector to which a first transmission optical fiber cable is coupled;
A first ferrule optically connected to the first transmission optical fiber cable coupled to the first transmission connector;
A first connection optically connected to the first ferrule;
A second transmission connector to which a second transmission optical fiber cable is coupled;
A second ferrule optically connected to a second transmission optical fiber cable coupled to the second transmission connector;
A second connection optically connected to the second ferrule;
A linear optical path in which the first connection portion and the second connection portion are optically connected to transmit an optical signal, and an optical signal optically connected to the linear optical path and incident from the first connection portion The first optical path for detecting an optical signal for branching at a predetermined branching ratio and the first optical path for detecting an optical signal for branching an optical signal connected to the linear optical path and incident from the second connecting section at a predetermined branching ratio. 2 optical paths are formed on a plane, and the first optical path and the second optical path are substantially U-shaped so that the straight optical path and one point of the curved portion of the substantially U-shaped optical path are in contact with each other. An optical waveguide substrate that emits an optical signal for detecting an optical signal in the same direction;
A third connection for optical signal detection optically connected to the first optical path for optical signal detection of the optical waveguide substrate;
A third ferrule for optical signal detection that is optically connected to the third connection portion and outputs an optical signal to the outside;
A fourth connection for optical signal detection optically connected to the second optical path for optical signal detection of the optical waveguide substrate;
A fourth ferrule for optical signal detection that is optically connected to the fourth connection portion and outputs an optical signal to the outside;
The first, second, third and fourth connecting portions, the first, second, third and fourth ferrules and the optical waveguide substrate are accommodated in predetermined positions, and the first and second transmission connectors are provided. On both sides in the longitudinal direction, a base part for fixing the third and fourth ferrules so as to protrude on the same side of the side surface and be arranged outside;
With
When an optical signal is incident on the optical waveguide substrate from the first connection portion through the first transmission connector and the first ferrule, an optical signal having a large intensity ratio passes through the second connection portion and the second ferrule. An optical signal for optical signal detection that is output to the second transmission connector and has a small intensity ratio is output from the third ferrule through the third connection portion,
When an optical signal is incident on the optical waveguide substrate from the second connection portion through the second transmission connector and the second ferrule, an optical signal having a large intensity ratio passes through the first connection portion and the first ferrule. An optical signal for detecting an optical signal having a small intensity ratio that is output to the first transmission connector is output from the fourth ferrule through the fourth connection portion .
[0012]
According to the optical signal detection component of claim 2,
The optical signal detection component according to claim 1,
When the intensity of the optical signal in the linear optical path in the optical waveguide substrate is I ₁ and the intensity of the optical signal in the first optical path or the second optical path for detecting the optical signal is I ₂ , 1.0 ≦ I Attenuation function with a branching ratio such that ₁ / I ₂ ≦ 9.0, increasing the amount output from the third and fourth ferrules and decreasing the amount output from the first and second ferrules It is characterized by having both.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
An optical signal detection component according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a structural diagram of an optical signal detection component showing an embodiment of the present invention. FIG. 1 (a) is a plan view, FIG. 1 (b) is a front view, FIG. 1 (c) is a bottom view, and FIG. d) is a left side view, and FIG. 1 (e) is a right side view. 2A and 2B are external structural views of the optical signal detection component showing the embodiment of the present invention. FIG. 2A is an external perspective view seen from the front side, and FIG. 2B is an external perspective view seen from the back side. is there. FIG. 3 is an internal structure diagram of an optical signal detection component showing an embodiment of the present invention. FIG. 4 is an explanatory diagram for explaining the branching operation of the optical waveguide substrate.
[0014]
As shown in FIGS. 1 and 2, the optical signal detection component includes a male connector 1 and a female connector 2, which are specific examples of two transmission connectors, and two optical signal outputs. A portion 3 and a base portion 4 are provided, and an optical waveguide substrate 5 is disposed in the base portion 4 as shown in FIG.
[0015]
The male connector 1 is a connector adapted to be fitted and coupled to a transmission optical fiber cable connector (not shown) through which an optical signal is transmitted, and is arranged on the left side in FIG.
As shown in detail in FIG. 3, the inside of the male connector 1 includes a plug frame 1a and a ferrule 1b.
[0016]
The female connector 2 is also a connector adapted to be fitted and coupled to a transmission optical fiber cable connector (not shown) through which an optical signal is transmitted, and is disposed on the right side in FIG.
As shown in detail in FIG. 3, the interior of the female connector 2 includes a housing 2a, a split sleeve 2b, and a ferrule 2c.
[0017]
The female connector 2 is configured in such a shape that the male connector 1 can be fitted. If the male connector 1 is inserted into the female connector 2, the plug frame 1a is guided and fixed by the housing 2a. Then, the ferrule 1b is fitted into the split sleeve 2b, and the ferrule 2c and the ferrule 1b come into contact with each other to form an optical path.
[0018]
In this embodiment, two such male connectors 1 and female connectors 2 are arranged in a straight line. As an optical fiber cable connector for transmission (not shown), a female connector 2 is provided on the side connected to the male connector 1 of the optical signal detection component, and a female connector 2 provided on the side connected to the female connector 2 of the optical signal detection component. A male connector 1 is employed.
Note that the structures of the male connector 1 and the female connector 2 are not particularly limited as long as the optical fiber cable can be coupled.
[0019]
Further, in the present embodiment, the male connector 1 and the female connector 2 are formed in a shape that can be fitted and fitted, but the male connector 1 and the female connector 2 are particularly related. The shape may not be present.
Furthermore, the male connector 1 may be connected to both sides, or the female connector 2 may be connected to both sides.
[0020]
Specifically, various connectors such as an SC connector, an FC connector, an SC2 connector, an MT connector, an MPO connector, an SF connector, an SSF connector, an MF connector, and an FO connector can be appropriately selected as these connectors.
[0021]
The optical signal output unit 3 is arranged side by side on one plane of the base unit 4 as shown in FIGS. Specifically, in the structure of the optical signal output unit 3 of the present embodiment, the ferrules 3a and 3b are the optical signal output unit 3, as shown in FIG. The ferrules 3a and 3b emit light branched and output from the optical waveguide substrate 5, as will be described in detail later.
[0022]
The structure of the optical signal output unit 3 is not limited to the ferrule, and a detection optical fiber cable connector (not shown) may be adopted for the optical signal output unit 3. Also in this case, the structure of the connector is not particularly limited as long as it can be coupled.
[0023]
The base portion 4 is for housing and fixing the male connector 1, the female connector 2, the optical signal output portion 3, and the optical waveguide substrate 5 at predetermined positions. For example, the base portion 4 is made of plastic or metal and is robust. It has light shielding properties.
[0024]
As shown in FIG. 3, the optical waveguide substrate 5 has a function of branching incident light by forming an optical path on a substrate made of quartz.
The optical waveguide substrate 5 is accommodated in the package 4 e of the base portion 4. The optical waveguide substrate 5 is connected to the ferrules 1b, 3a, 2c, and 3b via the connection portions 4a, 4b, 4c, and 4d, and an optical path is formed so that there is no leakage light.
[0025]
Next, the function of the optical waveguide substrate 5 will be described with reference to FIGS.
As shown in FIG. 3, the optical path 7a is to the ferrule 1b of the male connector 1, the optical path 7b is to the ferrule 3a of the signal output unit 3, the optical path 7c is to the ferrule 2c of the female connector 2, and the optical path 7d is to the optical signal output unit. Each of the three ferrules 3e is formed.
[0026]
Further, the optical waveguide substrate 5 is connected to the optical path 7a via the connection portion 4a, to the optical path 7b via the connection portion 4b, to the optical path 7c via the connection portion 4c, and to the optical path 7d via the connection portion 4d. It is made so that.
[0027]
Next, the operation of the optical signal detection component of this embodiment will be described focusing on the branching operation of the optical waveguide substrate 5.
The optical waveguide substrate 5 bifurcates an optical signal input via the male connector 1 or the female connector 2 at a predetermined intensity ratio and outputs the branched optical signal to the optical signal output connector 2.
[0028]
The optical waveguide substrate 5 does not matter in the input direction. For example, when an optical signal is input to the left male connector 1 in FIG. 3, as shown in FIG. 4, an arrow A is passed through the optical path 7a. The optical signal in the direction is input to the optical waveguide substrate 5, and the optical signal is output at the branching ratio I ₁ : I ₂ (where I ₁ + I ₂ = 1.0) through the optical paths 7c and 7d.
[0029]
Since the optical path 7c is an optical path of the ferrule 2c of the female connector 2, an optical signal having a large intensity ratio is output, and since the optical path 7d is an optical path of the ferrule 3b of the optical signal output unit 3, light having a small intensity ratio is output. Output a signal.
For example, if a ratio such as I ₁ : I ₂ = 0.95: 0.05, the optical signal is output from the female connector 2 with almost no attenuation, and the communication is hindered by the attenuation. A serious situation is avoided.
For example, if the branching ratio is I ₁ : I ₂ = 0.50: 0.50, the optical signal is attenuated in reverse and output from the female connector 2, and is attenuated by the optical signal detection component. Can have a function. In order to have an attenuation function, for example, it can be said that it has an attenuation function with I ₁ : I ₂ = 0.90: 0.10 as a boundary (1.0 ≦ I ₁ / I ₂ ≦ 9). .0 has a damping function).
[0030]
In addition, when an optical signal is input to the right female connector 2 in FIG. 3, an optical signal in the direction of arrow B is input to the optical waveguide substrate 5 through the optical path 7c as shown in FIG. Thus, the optical signals having the branching intensity ratio I ₁ : I ₂ are output from the optical paths 7a and 7b, respectively.
[0031]
Since the optical path 7a is an optical path of the ferrule 1b of the male connector 1, an optical signal having a large intensity ratio is output, and the optical path 7b is an optical path of the ferrule 3a of the optical signal output unit 3 in FIG. An optical signal having a small intensity ratio is output. Similarly, if the ratio of I ₁ : I ₂ = 0.95: 0.05, the optical signal is output from the male connector 1 with almost no attenuation, and there is a situation where communication is similarly hindered. Avoided.
For example, if the branching ratio is I ₁ : I ₂ = 0.50: 0.50, the optical signal is attenuated in reverse and output from the female connector 1, and is attenuated by the optical signal detection component. Can have a function. In order to have an attenuation function, for example, it can be said that it has an attenuation function with I ₁ : I ₂ = 0.90: 0.10 as a boundary (1.0 ≦ I ₁ / I ₂ ≦ 9). .0 has a damping function).
[0032]
As described above, when an optical signal is transmitted, an optical signal is output from one of the two optical signal output units 3, and whether the optical signal is transmitted to a transmission optical fiber cable (not shown) depending on the presence or absence of this output. It can be determined whether or not.
Furthermore, by detecting which one of the two optical signal output units 3 outputs, the transmission direction of the optical signal in a transmission optical fiber cable (not shown) can also be detected.
[0033]
The optical signal detection component of this embodiment has been described above. According to this embodiment, since the optical waveguide substrate 5 is used, there are the following advantages.
(1) The branch part for extracting the detection light in the prior art has a high manufacturing cost because it takes time to adjust the optical system. However, in the optical waveguide substrate 5 of the present invention, the branch part is simply in the package 4e of the base part 4. And connecting the waveguide of the optical waveguide substrate 5 and the ferrules 1b, 3a, 2c, and 3b through the connection portions 4a, 4b, 4c, and 4d, adjustment work and the like are not necessary.
(2) The optical waveguide substrate 5 is not limited in design because the bending direction is limited within a predetermined curvature, unlike the optical fiber coupler of the prior art. The degree of freedom in design can be increased.
(3) Although it is necessary to assemble so that the ferrule, the connecting portion, and the optical waveguide substrate form the optical path reliably, the object to be adjusted is the adjustment of one port (one to one) of the ferrule-to-optical waveguide substrate. Thus, it is not necessary to adjust a plurality of parts at the same time, making assembly easier and reducing the production cost, such as suppressing the occurrence of defective products.
[0034]
【The invention's effect】
As described above, according to the present invention, it is possible to provide an optical signal detection component that facilitates manufacturing without the restrictions required at the time of manufacturing, and realizes cost reduction and improvement in manufacturing workability.
[Brief description of the drawings]
FIG. 1 is an external structural view of an optical signal detection component showing an embodiment of the present invention.
FIG. 2 is an external structural view of an optical signal detection component showing an embodiment of the present invention.
FIG. 3 is an internal structure diagram of an optical signal detection component showing an embodiment of the present invention.
FIG. 4 is an explanatory diagram illustrating a branching operation of an optical waveguide substrate.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Male connector 1a Plug frame 1b Ferrule 2 Female connector 2a Housing 2b Split sleeve 2c Ferrule 3 Optical signal output part 3a Ferrule 3b Ferrule 4 Base part 4a, 4b, 4c, 4d Connection part 4e Package 5 Optical waveguide board 7a, 7b , 7c, 7d Optical path

Claims (2)

A first transmission connector to which a first transmission optical fiber cable is coupled;
A first ferrule optically connected to the first transmission optical fiber cable coupled to the first transmission connector;
A first connection optically connected to the first ferrule;
A second transmission connector to which a second transmission optical fiber cable is coupled;
A second ferrule optically connected to a second transmission optical fiber cable coupled to the second transmission connector;
A second connection optically connected to the second ferrule;
A linear optical path in which the first connection portion and the second connection portion are optically connected to transmit an optical signal, and an optical signal optically connected to the linear optical path and incident from the first connection portion The first optical path for detecting an optical signal for branching at a predetermined branching ratio and the first optical path for detecting an optical signal for branching an optical signal connected to the linear optical path and incident from the second connection section at a predetermined branching ratio 2 optical paths are formed on a plane, and the first optical path and the second optical path are substantially U-shaped so that the straight optical path and one point of the curved portion of the substantially U-shaped optical path are in contact An optical waveguide substrate that emits an optical signal for detecting an optical signal in the same direction;
A third connection for optical signal detection optically connected to the first optical path for optical signal detection of the optical waveguide substrate;
A third ferrule for optical signal detection that is optically connected to the third connection portion and outputs an optical signal to the outside;
A fourth connection for optical signal detection optically connected to the second optical path for optical signal detection of the optical waveguide substrate;
A fourth ferrule for optical signal detection that is optically connected to the fourth connection portion and outputs an optical signal to the outside;
The first, second, third and fourth connecting portions, the first, second, third and fourth ferrules and the optical waveguide substrate are accommodated in predetermined positions, and the first and second transmission connectors are provided. On both sides in the longitudinal direction, a base part for fixing the third and fourth ferrules so as to protrude on the same side of the side surface and be arranged outside;
With
When an optical signal is incident on the optical waveguide substrate from the first connection portion through the first transmission connector and the first ferrule, an optical signal having a large intensity ratio passes through the second connection portion and the second ferrule. An optical signal for optical signal detection that is output to the second transmission connector and has a small intensity ratio is output from the third ferrule through the third connection portion,
When an optical signal is incident on the optical waveguide substrate from the second connection portion through the second transmission connector and the second ferrule, an optical signal having a large intensity ratio passes through the first connection portion and the first ferrule. An optical signal detection component characterized in that an optical signal for optical signal detection that is output to the first transmission connector and has a small intensity ratio is output from the fourth ferrule through the fourth connection portion . The optical signal detection component according to claim 1,
When the intensity of the optical signal in the linear optical path in the optical waveguide substrate is I ₁ and the intensity of the optical signal in the first optical path or the second optical path for detecting the optical signal is I ₂ , 1.0 ≦ I Attenuation function with a branching ratio such that ₁ / I ₂ ≦ 9.0, increasing the amount output from the third and fourth ferrules and decreasing the amount output from the first and second ferrules An optical signal detection component characterized by having

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