JP2003149446A - Embedded optical part - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical part having structure capable of improving the strength of a groove processing part of a ferrule capillary and repeatedly resisting attachment/detachment. SOLUTION: The groove processing part in which an optical element of the ferrule capillary is embedded is inserted (covered) into a casing of parts having an optical connector function and stuck and fixed to the external parts casing, so that structural strength sufficient for practical use can be obtained.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical component in which an optical element such as an optical isolator, an optical attenuator or an optical filter used in optical communication or an optical measuring instrument is embedded in an optical fiber.

[0002]

2. Description of the Related Art Conventionally, as an optical component in which optical elements such as an optical isolator, an optical attenuator and an optical filter are embedded in a substrate, there are disclosed in Japanese Patent Laid-Open Nos. 3-63606 and 4-307.
The one described in 512 is known. This optical component is called an "embedded type", and is manufactured by forming a groove portion that crosses the optical fiber portion with a dicing saw etc. by fixing the embedded optical fiber on a substrate with resin etc. and embedding and fixing the optical element. It According to this, there is an advantage that the optical axis alignment is not required for manufacturing the optical isolator and the manufacturing is significantly facilitated. However, on the other hand, when the light output from the optical fiber passes through the optical element portion, diffraction occurs, which causes a problem that the thickness of the optical element becomes a neck and the insertion loss increases. On the other hand, JP-A-3
In -63606, a method is adopted in which the core of the optical fiber is expanded by local heating to reduce the diffractive power.

[0003]

When a ferrule capillary having a function as an optical fiber connector is used as an external support for a core-expanding optical fiber and an optical element,
When the grooved portion of the ferrule capillary is structurally weak, it is difficult to use it as an optical fiber connector when it is expected to repeatedly attach and detach. An object of the present invention is to provide an optical component having a structure in which the grooved portion of a ferrule capillary is increased in strength and can be repeatedly attached and detached.

[0004]

In order to solve this problem, the present invention inserts (covers) a grooved portion in which an optical element of a ferrule capillary is embedded in a housing of a component having an optical connector function. By being adhesively fixed to the external component housing, the structure has a practically sufficient structural strength. That is, the present invention is a polishing treatment for functioning as a connector connectable to another optical fiber ferrule on at least one end surface of an external support having an optical fiber inserted and bonded in a through hole of an external support (eg, ferrule capillary). Is formed, a groove is formed in the external support member across the optical fiber, and in the optical fiber ferrule capillary in which an optical element having various functions is embedded in the groove portion, a groove portion peripheral portion in which the optical element is embedded, Provided is an embedded optical component, which is covered and supported by an external supporting member having a function of supporting a ferrule capillary. As a result, it is possible to obtain an embedded optical component having an optical connector function capable of withstanding repeated attachment and detachment.

As shown in the first embodiment, according to one aspect of the present invention, at least one end face of a ferrule having a through hole into which an optical fiber is inserted and bonded functions as a connector connectable to another optical fiber ferrule. Optical fiber ferrule in which a groove is formed in the ferrule across the optical fiber and an optical element having various functions is embedded in the groove portion, an optical cable having another optical fiber, and the optical fiber. It is composed of an external supporting member having a through hole that fits and supports one end of the fiber ferrule and one end of the optical cable, and one end of the optical fiber ferrule has a groove circumference in which the optical element is embedded by the external supporting member. There is provided an optical element-embedded optical component, wherein the part is covered and supported by the inner wall of the through hole.

As shown in the second embodiment, according to another embodiment of the present invention, both end faces of the ferrule having a through hole into which an optical fiber is inserted and bonded functions as a connector connectable to another optical fiber ferrule. Optical fiber ferrule in which a groove is formed in the ferrule across the optical fiber, and an optical element having various functions is embedded in the groove, and both ends of the optical fiber ferrule and other optical fibers. The optical fiber ferrule comprises an external supporting member having a through hole for fitting and supporting one end of the ferrule, and an elastic split sleeve provided in alignment with the through hole for holding the other optical fiber ferrule. Is characterized in that the peripheral portion of the groove in which the optical element is embedded is covered and supported by the inner wall of the through hole by the external supporting member. Optical elements embedded optical parts that are provided.

As shown in Example 3, according to still another aspect of the present invention, one end face of a ferrule having a through hole into which an optical fiber is inserted and bonded functions as a connector connectable to another optical fiber ferrule. Polishing treatment for forming a groove in the ferrule across the optical fiber, and the optical fiber ferrule in which an optical element having various functions is embedded in the groove and one end of the optical fiber ferrule are fitted and supported. And a semiconductor laser light source coupled to an optical fiber of the optical fiber ferrule, one end of the optical fiber ferrule has a groove peripheral portion in which the optical element is embedded by the external support member. Provided is an optical element-embedded optical component, which is covered and supported by an inner wall of a through hole.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment using an optical element functioning as an optical isolator will be described below. It should be understood that the present invention can be applied not only to the optical isolator but also to an optical component including an external supporting member such as a ferrule capillary in which optical elements such as an optical attenuator and an optical filter are incorporated together with an optical fiber.

[0009]

(Embodiment 1) FIG. 1 illustrates a fiber connector built-in type optical isolator according to a first embodiment of the present invention. A cross groove 5 is formed in a ferrule capillary 1 in which an optical fiber 2 is embedded, and an optical isolator element 4 is formed therein.
(Faraday rotator sandwiched between two polarizers or birefringent plates, etc.) is inserted and fixed by adhesion. The end surface of the capillary 1 is polished for optical coupling. An inner hole for fitting and holding the capillary 1 in the metal housing 10, a larger diameter inner hole for holding the magnet 6 that gives a magnetic field to the Faraday rotator, the optical fiber 7, the sleeve 8 and the optical fiber coating. 9 has a smaller diameter inner hole for holding the optical cable. Optical cable is adhesive 11
Is coupled to the housing 10, and the optical fiber 7 is optically coupled to the end face of the optical fiber 2 of the ferrule capillary 1 at the inner end of the optical fiber 7. Optical fiber 1 is groove 5
Since the portion facing the surface has been preheated to have an enlarged core diameter, and the groove 5 is formed in that portion to insert the optical isolator element 4, a lens system for optical coupling becomes unnecessary. The feature of this embodiment resides in that the periphery of the optical isolator element 4 of the capillary 1 is structurally strengthened by being adhesively fixed to the inner hole of the metal housing or the magnet 6 attached to the inner hole. Therefore, in this example in which the capillary 1 acts as a connector, stress concentration on the groove 5 of the capillary 1 can be avoided, and sufficient strength that can be repeatedly attached and detached can be obtained.

(Embodiment 2) FIG. 2 illustrates an embodiment of an optical isolator incorporating a ferrule connector. In this embodiment, there is provided a ferrule connector built-in type optical isolator configured by using an embedded optical isolator and a split sleeve in a housing having a shape corresponding to various connectors. According to this example, in addition to the benefits of the first embodiment, a low-cost inline optical isolator that does not use a lens can be easily incorporated by a commercially available connector connection. Referring to FIG. 2, a cross groove 5 is formed in a ferrule capillary 1 in which an optical fiber 2 is embedded,
An optical isolator element 4 (such as one in which a Faraday rotator is sandwiched between two polarizers or birefringent plates) is inserted and fixed there. Both end faces of the capillary 1 are polished for optical coupling. Metal housings 13 and 15
Is provided with an inner hole for fitting and holding the capillary 1, and a metal housing 13 and a larger diameter inner hole for holding the magnet 6 for applying a magnetic field to the Faraday rotator.
A space for accommodating the magnet 6 is formed between the metal housing 15 and the metal housing 13, and the magnet 6 is held in a regular position by closely fitting each other. The outer peripheral protrusion 14 of the metal housing 15 has a circumferential groove having a shape complementary to that of the inner peripheral protrusion of the plastic housing 12. Metal housing 1
Elastic split sleeves 16 and 17 are held on the inner surfaces of 3 and 15. Thereby, both ends of the optical fiber ferrule 1 of the ferrule-embedded optical isolator 18 can be easily coupled to another optical fiber ferrule. The optical fiber 2 is preheated so as to have an enlarged core diameter in the portion facing the groove 5, and the groove 5 is formed in that portion and the optical isolator element 4 is inserted into the optical fiber 2 to form a lens system for optical coupling. Is unnecessary. In addition to the above, the features of this embodiment are structurally strengthened by adhesively fixing the periphery of the optical isolator element 4 of the capillary 1 to the inner hole of the metal housing 13 or the magnet 6 attached to the inner hole. It is in. Therefore, in this example in which the capillary 1 acts as a connector, stress concentration on the groove 5 of the capillary 1 can be avoided, and sufficient strength that can be repeatedly attached and detached can be obtained.

(Embodiment 3) FIGS. 3 to 4 show a third embodiment of the present invention, in which the present invention is applied to a semiconductor laser module with a built-in optical isolator. Planar mounting LD
In the module, by embedding the optical isolator in the one-end fiber cut ferrule connector, a compact LD module with high characteristics can be realized. FIG. 3 shows an optical fiber ferrule used in this embodiment and its reinforcing structure. In FIG. 3, a transverse groove 5 is formed in a ferrule capillary 1 in which an optical fiber 2 is embedded, and an optical isolator element 4 (such as two Faraday rotators sandwiched between two polarizers or birefringent plates) is inserted therein. And fix it with adhesive. Further, a magnet 6 is inserted into the groove 5 of the ferrule capillary 1, and the left end surface of the capillary 1 is polished and finished for optical coupling. An arc-shaped metal housing 20 is attached so as to cover the optical isolator element 4 and the magnet 5 at the position of the groove 5 of the ferrule capillary 1 and fixed with an adhesive. This reinforces the strength of the groove 5. The optical fiber 2 is preheated so as to have an enlarged core diameter in the portion facing the groove 5, and the groove 5 is formed in that portion and the optical isolator element 4 is inserted into the optical fiber 2 to form a lens system for optical coupling. Is unnecessary. In FIG. 4, the optical isolator built-in ferrule capillary 1 assembled as shown in FIG. 3 is built in the LD module. The LD module includes a ceramic substrate 22 and a Si-V substrate 22.
The LD chip 24 and the monitor PD 25 supported by the grooved stem 23 are arranged, the lead frame 26 is attached to the back surface of the substrate 22, these are housed in the epoxy resin transfer mold 21, and fixed with the transparent mold resin 27. It is a thing. In addition to the above, the feature of this embodiment resides in that the metal housing 20 is adhesively fixed around the optical isolator element 4 of the capillary 1 to structurally strengthen it. Therefore, in this example in which the capillary 1 acts as a connector, stress concentration on the groove 5 of the capillary 1 can be avoided, and sufficient strength that can be repeatedly attached and detached can be obtained.

[0012]

As described above, according to the present invention, the practical strength of using a ferrule capillary having a function of supporting an optical fiber and an optical element as an optical fiber connector,
In addition to the effect of having durability, the advantages described in each of the embodiments can be obtained.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of an optical component with an embedded optical isolator element according to a first embodiment of the present invention.

FIG. 2 is a sectional view of an optical component with an embedded optical isolator element according to a second embodiment of the present invention.

FIG. 3 is a sectional view of an optical component with embedded optical isolator element according to a third embodiment of the present invention.

4 is a cross-sectional view of an LD module using the optical component with embedded optical isolator element of FIG.

[Explanation of symbols]

1 Ferrule capillary 2 optical fiber 3 Optical fiber core expansion area 4 Optical isolator element 5 grooves 6 magnets 10 metal housing 13, 15 Stainless steel member (metal housing) 16, 17 split sleeve 20 metal housing 21 Transfer Mold

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[Procedure amendment]

[Submission date] August 23, 2002 (2002.8.2)
3)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

[Title of Invention] Embedded optical component

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical component in which an optical element such as an optical isolator, an optical attenuator or an optical filter used in optical communication or an optical measuring instrument is embedded in an optical fiber.

[0002]

2. Description of the Related Art Conventionally, as an optical component in which optical elements such as an optical isolator, an optical attenuator and an optical filter are embedded in a substrate, there are disclosed in Japanese Patent Laid-Open Nos. 3-63606 and 4-307.
The one described in 512 is known. This optical component is called an "embedded type", and is manufactured by forming a groove portion that crosses the optical fiber portion with a dicing saw etc. by fixing the embedded optical fiber on a substrate with resin etc. and embedding and fixing the optical element. It According to this, there is an advantage that the optical axis alignment is not required for manufacturing the optical isolator and the manufacturing is significantly facilitated. However, on the other hand, when the light output from the optical fiber passes through the optical element portion, diffraction occurs, which causes a problem that the thickness of the optical element becomes a neck and the insertion loss increases. On the other hand, JP-A-3
In -63606, a method is adopted in which the core of the optical fiber is expanded by local heating to reduce the diffractive power.

[0003]

When a ferrule capillary having a function as an optical fiber connector is used as an external support for a core-expanding optical fiber and an optical element,
When the grooved portion of the ferrule capillary is structurally weak, it is difficult to use it as an optical fiber connector when it is expected to repeatedly attach and detach. An object of the present invention is to provide an optical component having a structure in which the grooved portion of a ferrule capillary is increased in strength and can be repeatedly attached and detached.

[0004]

SUMMARY OF THE INVENTION To solve this problem, the present invention provides an optical connector inside a housing of a component having a function of an optical connector .
Insert (cover) the grooved part in which the optical element of the ferrule capillary is embedded into the inner hole of the magnet or housing ,
It is constructed so as to have practically sufficient structural strength by being adhesively fixed to the external component housing. That is, the present invention is a polishing treatment for functioning as a connector connectable to another optical fiber ferrule on at least one end surface of an external support having an optical fiber inserted and bonded in a through hole of an external support (eg, ferrule capillary). Is formed, a groove is formed in the external support member across the optical fiber, and in the optical fiber ferrule capillary in which an optical element having various functions is embedded in the groove portion, a groove portion peripheral portion in which the optical element is embedded, (EN) Provided is an embedded optical component which is supported by being covered with a magnet having a function of supporting a ferrule capillary or an inner hole of a housing . As a result, it is possible to obtain an embedded optical component having an optical connector function capable of withstanding repeated attachment and detachment. Also the above house
The ferrule capillaries can be
To the semiconductor laser module in a fixed relationship
It

As shown in the first embodiment, according to one aspect of the present invention, at least one end face of a ferrule having a through hole into which an optical fiber is inserted and bonded functions as a connector connectable to another optical fiber ferrule. Optical fiber ferrule in which a groove is formed in the ferrule across the optical fiber and an optical element having various functions is embedded in the groove portion, an optical cable having another optical fiber, and the optical fiber. is configured with one end portion of the optical cable and one end of the fiber ferrule from an external support member having a through hole for fitting and supporting said outer support section
A magnet for applying a magnetic field to the optical element is provided in the inner hole of the material.
Provided is an optical element-embedded optical component , wherein a peripheral portion of the groove of the ferrule in which the optical element is embedded is covered and supported by the magnet .

As shown in the second embodiment, according to another embodiment of the present invention, both end faces of the ferrule having a through hole into which an optical fiber is inserted and bonded functions as a connector connectable to another optical fiber ferrule. Optical fiber ferrule in which a groove is formed in the ferrule across the optical fiber, and an optical element having various functions is embedded in the groove, and both ends of the optical fiber ferrule and other optical fibers. The optical fiber ferrule comprises an external supporting member having a through hole for fitting and supporting one end of the ferrule, and an elastic split sleeve provided in alignment with the through hole for holding the other optical fiber ferrule. Is a groove peripheral portion in which the optical element is embedded by the external support member is attached to the inner wall of the through hole ,
Optical elements embedded optical component characterized in that it is more covered with supported magnet for applying a magnetic field to the optical device is provided.

As shown in Example 3, according to still another aspect of the present invention, one end face of a ferrule having a through hole into which an optical fiber is inserted and bonded functions as a connector connectable to another optical fiber ferrule. Polishing treatment for forming a groove in the ferrule across the optical fiber, and the optical fiber ferrule in which an optical element having various functions is embedded in the groove and one end of the optical fiber ferrule are fitted and supported. And a semiconductor laser light source coupled to the optical fiber of the optical fiber ferrule. One end of the optical fiber ferrule has a groove peripheral portion in which the optical element is embedded by the housing and the through hole is formed. Is covered and supported by the inner wall of the housing, and the housing has a semiconductor laser on one side thereof.
Optical elements embedded optical component is supported on the surface of the substrate. The light source and said Rukoto is provided.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment using an optical element functioning as an optical isolator will be described below. It should be understood that the present invention can be applied not only to the optical isolator but also to an optical component including an external supporting member such as a ferrule capillary in which optical elements such as an optical attenuator and an optical filter are incorporated together with an optical fiber.

[0009]

(Embodiment 1) FIG. 1 illustrates a fiber connector built-in type optical isolator according to a first embodiment of the present invention. A cross groove 5 is formed in a ferrule capillary 1 in which an optical fiber 2 is embedded, and an optical isolator element 4 is formed therein.
(Faraday rotator sandwiched between two polarizers or birefringent plates, etc.) is inserted and fixed by adhesion. The end surface of the capillary 1 is polished for optical coupling. An inner hole for fitting and holding the capillary 1 in the metal housing 10, a larger diameter inner hole for holding the magnet 6 that gives a magnetic field to the Faraday rotator, the optical fiber 7, the sleeve 8 and the optical fiber coating. 9 has a smaller diameter inner hole for holding the optical cable. Optical cable is adhesive 11
Is coupled to the housing 10, and the optical fiber 7 is optically coupled to the end face of the optical fiber 2 of the ferrule capillary 1 at the inner end of the optical fiber 7. Optical fiber 1 is groove 5
Since the portion facing the surface has been preheated to have an enlarged core diameter, and the groove 5 is formed in that portion to insert the optical isolator element 4, a lens system for optical coupling becomes unnecessary. The feature of this embodiment is that the periphery of the optical isolator element 4 of the capillary 1 is structurally strengthened by being adhesively fixed to the magnet 6 attached to the inner hole of the metal housing. Therefore, in this example in which the capillary 1 acts as a connector, stress concentration on the groove 5 of the capillary 1 can be avoided, and sufficient strength that can be repeatedly attached and detached can be obtained.

(Embodiment 2) FIG. 2 illustrates an embodiment of an optical isolator incorporating a ferrule connector. In this embodiment, there is provided a ferrule connector built-in type optical isolator configured by using an embedded optical isolator and a split sleeve in a housing having a shape corresponding to various connectors. According to this example, in addition to the benefits of the first embodiment, a low-cost inline optical isolator that does not use a lens can be easily incorporated by a commercially available connector connection. Referring to FIG. 2, a cross groove 5 is formed in a ferrule capillary 1 in which an optical fiber 2 is embedded,
An optical isolator element 4 (such as one in which a Faraday rotator is sandwiched between two polarizers or birefringent plates) is inserted and fixed there. Both end faces of the capillary 1 are polished for optical coupling. Metal housings 13 and 15
Is provided with an inner hole for fitting and holding the capillary 1, and a metal housing 13 and a larger diameter inner hole for holding the magnet 6 for applying a magnetic field to the Faraday rotator.
A space for accommodating the magnet 6 is formed between the metal housing 15 and the metal housing 13, and the magnet 6 is held in a regular position by closely fitting each other. The outer peripheral protrusion 14 of the metal housing 15 has a circumferential groove having a shape complementary to that of the inner peripheral protrusion of the plastic housing 12. Metal housing 1
Elastic split sleeves 16 and 17 are held on the inner surfaces of 3 and 15. Thereby, both ends of the optical fiber ferrule 1 of the ferrule-embedded optical isolator 18 can be easily coupled to another optical fiber ferrule. The optical fiber 2 is preheated so as to have an enlarged core diameter in the portion facing the groove 5, and the groove 5 is formed in that portion and the optical isolator element 4 is inserted into the optical fiber 2 to form a lens system for optical coupling. Is unnecessary. In addition to the above, the features of this embodiment are structurally strengthened by adhesively fixing the periphery of the optical isolator element 4 of the capillary 1 to the inner wall of the magnet 6 attached to the inner hole of the metal housing 13. There is a point. Therefore, in this example in which the capillary 1 acts as a connector, stress concentration on the groove 5 of the capillary 1 can be avoided, and sufficient strength that can be repeatedly attached and detached can be obtained.

(Embodiment 3) FIGS. 3 to 4 show a third embodiment of the present invention, in which the present invention is applied to a semiconductor laser module with a built-in optical isolator. Planar mounting LD
In the module, by embedding the optical isolator in the one-end fiber cut ferrule connector, a compact LD module with high characteristics can be realized. FIG. 3 shows an optical fiber ferrule used in this embodiment and its reinforcing structure. In FIG. 3, a transverse groove 5 is formed in a ferrule capillary 1 in which an optical fiber 2 is embedded, and an optical isolator element 4 (such as two Faraday rotators sandwiched between two polarizers or birefringent plates) is inserted therein. And fix it with adhesive. Further, a magnet 6 is inserted into the groove 5 of the ferrule capillary 1, and the left end surface of the capillary 1 is polished and finished for optical coupling. An arc-shaped metal housing 20 is attached so as to cover the optical isolator element 4 and the magnet 5 at the position of the groove 5 of the ferrule capillary 1 and fixed with an adhesive. This reinforces the strength of the groove 5. The optical fiber 2 is preheated so as to have an enlarged core diameter in the portion facing the groove 5, and the groove 5 is formed in that portion and the optical isolator element 4 is inserted into the optical fiber 2 to form a lens system for optical coupling. Is unnecessary. In FIG. 4, the optical isolator built-in ferrule capillary 1 assembled as shown in FIG. 3 is built in the LD module. The LD module includes a ceramic substrate 22 and a Si-V substrate 22.
The LD chip 24 and the monitor PD 25 supported by the grooved stem 23 are arranged, the lead frame 26 is attached to the back surface of the substrate 22, these are housed in the epoxy resin transfer mold 21, and fixed with the transparent mold resin 27. It is a thing. In addition to the above, the features of this embodiment are structurally strengthened by adhesively fixing the metal housing 20 around the optical isolator element 4 of the capillary 1, and one surface of the housing 20 is the base of the LD module.
It is at the point of being supported by the surface of the plate 22 . Therefore, in this example in which the capillary 1 acts as a connector, stress concentration on the groove 5 portion of the capillary 1 can be avoided, sufficient strength to withstand repeated attachment / detachment can be obtained , and further, it can withstand laser light.
The optical isolator has a fixed direction.

[0012]

As described above, according to the present invention, the practical strength of using a ferrule capillary having a function of supporting an optical fiber and an optical element as an optical fiber connector,
In addition to the effect of having durability, the advantages described in each of the embodiments can be obtained.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of an optical component with an embedded optical isolator element according to a first embodiment of the present invention.

FIG. 2 is a sectional view of an optical component with an embedded optical isolator element according to a second embodiment of the present invention.

FIG. 3 is a sectional view of an optical component with embedded optical isolator element according to a third embodiment of the present invention.

4 is a cross-sectional view of an LD module using the optical component with embedded optical isolator element of FIG.

[Explanation of Codes] 1 Ferrule Capillary 2 Optical Fiber 3 Optical Fiber Core Expansion Area 4 Optical Isolator Element 5 Groove 6 Magnet 10 Metal Housing 13, 15 Stainless Steel Member (Metal Housing) 16, 17 Split Sleeve 20 Metal Housing 21 Transfer Mold ── ─────────────────────────────────────────────────── ─

[Procedure amendment]

[Submission date] February 20, 2003 (2003.2.2)
0)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be amended] Claims

[Correction method] Change

[Correction content]

[Claims]

3. A ferrule having a through hole in which an optical fiber is inserted and adhered is subjected to a polishing treatment so as to function as a connector connectable to another optical fiber ferrule, and the ferrule is traversed across the optical fiber. An optical fiber ferrule in which a groove is formed and an optical element having various functions is embedded in the groove, and an external supporting member having a through hole for fitting and supporting both ends of the optical fiber ferrule and one end of another optical fiber ferrule. An elastic split sleeve provided in alignment with the through hole for holding the other optical fiber ferrule, and a magnet attached to the external support member for applying a magnetic field to the optical element of the optical fiber ferrule. And a groove portion in which the optical element of the optical fiber ferrule is embedded and its vicinity.
An optical element-embedded optical component, wherein a peripheral portion of the optical fiber ferrule adjacent thereto is covered and supported by an inner wall of the magnet.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0004

[Correction method] Change

[Correction content]

[0004]

In order to solve this problem, the present invention provides a grooved portion in which an optical element of a ferrule capillary is embedded in an inner wall of a magnet in a housing of a component having an optical connector function, and its vicinity. Cover the outer circumference of the ferrule
Thus , by being adhesively fixed to the external component housing, the structural strength is practically sufficient. That is, the present invention is an external support (eg, ferrule capillary).
At least one end surface of the external support having an optical fiber inserted and bonded into the through hole is subjected to a polishing treatment to function as a connector connectable to another optical fiber ferrule,
A groove is formed in the external support member across the optical fiber, and in the optical fiber ferrule capillary in which an optical element having various functions is embedded in the groove portion, the groove portion peripheral portion in which the optical element is embedded is supported by the ferrule capillary. Provided is an embedded optical component, which is covered with and supported by an inner wall of a magnet having a function of. As a result, it is possible to obtain an embedded optical component having an optical connector function capable of withstanding repeated attachment and detachment. Further, by forming the mounting surface on the housing, the ferrule capillaries can be mounted on the semiconductor laser module in a fixed relationship.

[Procedure 3]

[Document name to be amended] Statement

[Name of item to be corrected] 0005

[Correction method] Change

[Correction content]

As shown in the first embodiment, according to one aspect of the present invention, at least one end face of a ferrule having a through hole into which an optical fiber is inserted and bonded functions as a connector connectable to another optical fiber ferrule. Optical fiber ferrule in which a groove is formed in the ferrule across the optical fiber and an optical element having various functions is embedded in the groove portion, an optical cable having another optical fiber, and the optical fiber. An outer supporting member having a through hole for fitting and supporting one end of the fiber ferrule and one end of the optical cable, and a magnet for applying a magnetic field to the optical element is attached to an inner hole of the outer supporting member. supports the circumferential face of the ferrule of the groove Shubu and its vicinity embedded optical element of said ferrule covered by the magnet Optical elements embedded type optical component, wherein the door is provided.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0006

[Correction method] Change

[Correction content]

As shown in the second embodiment, according to another embodiment of the present invention, both end faces of the ferrule having a through hole into which an optical fiber is inserted and bonded functions as a connector connectable to another optical fiber ferrule. Optical fiber ferrule in which a groove is formed in the ferrule across the optical fiber, and an optical element having various functions is embedded in the groove, and both ends of the optical fiber ferrule and other optical fibers. The optical fiber ferrule comprises an external supporting member having a through hole for fitting and supporting one end of the ferrule, and an elastic split sleeve provided in alignment with the through hole for holding the other optical fiber ferrule. the outer peripheral surface of the embedded optical elements groove Shubu and its vicinity is attached to the inner wall of the through hole by the outer support member The optical element embedded type optical component characterized in that it is supported and covered by the magnet for applying a magnetic field to the optical device is provided.

Claims (4)

[Claims] 1. An optical fiber is inserted and bonded, and at least one end surface of a ferrule having a through hole is subjected to a polishing treatment so as to function as a connector connectable to another optical fiber ferrule, and the ferrule is traversed across the optical fiber. In an optical fiber ferrule in which a groove is formed in a ferrule, and an optical element having various functions is embedded in the groove portion, the groove portion peripheral portion in which the optical element is embedded is supported by an external supporting member having a function of supporting a ferrule capillary. An optical element-embedded optical component characterized by the above. 2. An optical fiber is inserted and bonded, and at least one end face of the ferrule having a through hole is subjected to a polishing treatment so as to function as a connector connectable to another optical fiber ferrule, and the ferrule is traversed across the optical fiber. An optical fiber ferrule in which a groove is formed in a ferrule and an optical element having various functions is embedded in the groove, an optical cable having another optical fiber, and one end of the optical fiber ferrule and one end of the optical cable are fitted to each other. An outer supporting member having a through hole for supporting the optical fiber ferrule, wherein one end of the optical fiber ferrule is supported such that a groove peripheral portion in which the optical element is embedded by the outer supporting member is covered by an inner wall of the through hole. An optical element-embedded optical component characterized by: 3. A ferrule having a through hole in which an optical fiber is inserted and adhered is subjected to a polishing treatment so as to function as a connector connectable to another optical fiber ferrule, and the ferrule is traversed across the optical fiber. An optical fiber ferrule in which a groove is formed and an optical element having various functions is embedded in the groove, and an external supporting member having a through hole for fitting and supporting both ends of the optical fiber ferrule and one end of another optical fiber ferrule. And an elastic split sleeve provided in alignment with the through hole for holding the other optical fiber ferrule, and the optical fiber ferrule has a groove portion peripheral portion in which the optical element is embedded by the external support member. An optical element-embedded optical component, which is covered and supported by an inner wall of a through hole. 4. A ferrule having a through hole in which an optical fiber is inserted and adhered is polished to function as a connector connectable to another optical fiber ferrule, and the ferrule is traversed across the optical fiber. A groove is formed in the optical fiber ferrule in which an optical element having various functions is embedded in the groove, a housing having a through hole for fitting and supporting one end of the optical fiber ferrule, and an optical fiber of the optical fiber ferrule. The optical fiber ferrule is configured such that one end portion of the optical fiber ferrule is supported by an outer wall of the through hole having a groove peripheral portion in which the optical element is embedded. Optical element embedded optical component.