JP2005242314A - Optical receptacle having optical isolator and optical module using the optical receptacle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problems that the shape of a transceiver which uses an optical module using an optical receptacle is generally standardized, but required space for an electric circuit is increased when the modulation speed to be added to a semiconductor laser is increased, i.e., the length of the optical receptacle must be reduced to secure the space of the electric circuit and moreover, the total length is increased due to the structure for arranging an optical isolator at the end face of a fiber stub for the case of an optical receptacle having the optical isolator. <P>SOLUTION: The optical receptacle having the optical isolator is provided with an optical isolator 9 which is constituted by pasting together the optical surfaces of polarizers 6a and 6b and a Faraday rotator 7 and a sleeve 3 in which a plug ferrule 2 for an optical connector is held from the opening of one side and the other side is inserted and fixed to the opening of a through-hole 40 formed on a holder 4. The opening of the through-hole 40 formed on the holder 4 is closed by a plate shaped body 10 through which light beams are transmissive. The tip of the plug ferrule 2 is abutted on the surface of one side of the plate shaped body 10 and the optical surface of the optical isolator 9 is joined and fixed to the surface of the other side of the plate shaped body 10. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an optical receptacle with an optical isolator used for optical communication and an optical module using the same.

  An optical module for converting an optical signal into an electric signal has a structure in which an optical element such as a semiconductor laser or a photodiode is housed in a case, and the optical signal is introduced or derived through an optical fiber. In addition, a receptacle-type optical module in which a connector is connected among optical modules has an optical element at one end of the optical receptacle and an optical connector plug ferrule having an optical fiber made of quartz glass or the like at the other end. To do.

  Conventionally, an optical module using an optical receptacle is used only for a low-speed communication application such as a LAN, and an optical module using an optical fiber pigtail is used for a high-speed communication application such as a trunk line system.

  However, in recent years, there has been a demand for higher communication speeds in LANs and the like, and optical modules using optical receptacles are much smaller than optical modules using optical fiber pigtails. There has also been a demand for higher communication speeds in the optical modules used.

  In order to increase the communication speed, a high-performance semiconductor laser is used, and in order to obtain stable characteristics, it is necessary to prevent reflected return light. Therefore, an optical isolator must be inserted in the optical path. Therefore, as shown in FIG. 8, an optical receptacle in which an optical isolator is arranged has been proposed (see Patent Document 1).

  As shown in FIG. 8, the optical receptacle 22 includes a ferrule 17 made of a ceramic material such as zirconia or alumina, and a fiber stub 18 obtained by inserting and fixing an optical fiber 16 made of quartz glass or the like in the central through hole of the ferrule 17. The rear end portion is fixed to the holder 20 by press-fitting, the tip end portion is inserted into the inner hole of the sleeve 19, and they are press-fitted or adhesively fixed to the sleeve case 21.

  The end face of the optical fiber 16 in the fiber stub 18 is mirror-polished to a curved surface having a curvature radius of about 5 to 30 mm in order to reduce the connection loss at the time of contact, and the opposite end face is emitted from the optical element 23 such as an LD. In order to prevent the reflected light from being reflected at the tip of the optical fiber 16 and returning to the optical element, the optical signal is mirror-polished on the inclined surface together with the ferrule 17.

  At this time, the outer diameter of the ferrule 17 is about φ2.5 mm for the type connecting the SC connector, about φ1.25 mm for the small type connecting the LC connector, and the outer diameter tolerance is ± 1 μm or less. The optical fiber 16 provided in the hole has an outer diameter of about 125 μm and an outer diameter tolerance of about ± 1 μm, which is defined by the JIS standard, the IEC standard, etc. Conventionally, an optical signal formed at the center of the optical fiber 16 Each core (sleeve 19, ferrule 17, etc.) is processed with high accuracy so that cores (not shown) having a diameter of about 10 μm that propagate through the core are connected with low loss. The connector plug ferrule 15 is held stably and with high accuracy.

  Further, an optical isolator 26 including a polarizer, a Faraday rotator, and a polarizer is provided on the end face of the fiber stub 18, and a ring-shaped magnet 27 is attached to the holder 20 so as to surround the optical isolator 26. Bonded and fixed.

  When an optical module is configured using the optical receptacle 22 described above, a case 25 including an optical element 23 and a lens 24 is joined to the rear end surface of the optical receptacle 22 including the fiber stub 18 by welding, An optical connector plug ferrule can be inserted into the sleeve 19 from the other end face side of the optical receptacle 22, and the end faces of the optical fibers can be brought into contact with each other to exchange optical signals.

  It is desirable that the optical elements used in these optical modules be hermetically sealed in order to prevent moisture contained in the outside air from entering. However, there has been no example of an optical receptacle with an optical isolator having a hermetically sealed structure, and a structure without an optical isolator is as shown in FIG.

The hermetic sealing structure of the optical receptacle 22 bonded to the optical module allows the fiber stub 18 of the optical receptacle 22 to protrude from the holder 20 in order to realize hermetic sealing using the side surface of the fiber stub 18. A dam 28 formed in a digging shape is provided in a part of the holder 20 on the side of the optical receptacle 22 from which the fiber stub 18 protrudes, and the dam 28 is filled with resin as a sealing material 29 or the fiber stub ferrule By metallizing the outer periphery and filling solder into the dam 28 as a sealing material 29, the side surface of the fiber stub 18 and the bottom surface of the dam 28 are brought into close contact with each other by the sealing material 29. The space between the inner walls is shielded from the outside air to realize hermetic sealing (see Patent Document 2).
JP 2003-75679 A JP 1998-239567 A

  However, in general, the shape of a transceiver using an optical module using an optical receptacle is standardized, and when the modulation speed applied to the semiconductor laser is increased, the space required for the electric circuit for that is increased. In other words, in order to secure the space of the electric circuit, it is required to shorten the optical receptacle.

  In the case of the conventional optical receptacle 22 with an optical isolator shown in FIG. 9, the fixing strength varies depending on the contact area between the holder 20 and the fiber stub 18, but if the total length is shortened, the contact area becomes smaller, and the optical connector connection is reduced. In this case, there is a problem that the fiber stub 18 moves to deteriorate the reproducibility of the connection loss.

  Furthermore, the outer diameter of the fiber stub 18 is processed with very high accuracy in order to connect cores (not shown) having a diameter of about 10 μm that propagate optical signals formed at the center of the optical fiber 16 with low loss. In order to directly bond the cores to each other, the curved surfaces must be mirror-polished. However, if the total length is shortened, there is a problem that the processing is very troublesome.

  In the hermetic sealing structure as shown in FIG. 9, the optical fiber 16 and the ferrule 17 are fixed by an adhesive, which is insufficient as an airtight structure.

  In addition to the humidity, the optical module is also required to be reliable against temperature changes. As shown in FIG. 9, the side surface of the ceramic column such as the ferrule 17 and the metal such as the holder 20 are airtight. In order to ensure and join, even if it is sealed with an adhesive, it has a very weak structure with respect to temperature change due to the difference in linear expansion coefficient.

  Furthermore, since the fiber stub 18 is longer than usual, there is a problem that the entire length becomes longer.

  In view of the above-described problems, an optical receptacle with an optical isolator of the present invention holds an optical isolator configured by bonding optical surfaces of a polarizer and a Faraday rotator, and a plug ferrule for an optical connector from an opening on one side. In the optical receptacle having a sleeve formed by inserting and fixing the other side into a through hole formed in the holder, the opening of the through hole formed in the holder is closed with a plate-like body capable of transmitting light, and the plate The tip of the plug ferrule can be brought into contact with one surface of the body, and the optical surface of the optical isolator is bonded and fixed to the other surface.

  An optical receptacle with an optical isolator according to another invention holds an optical isolator configured by bonding optical surfaces of a polarizer and a Faraday rotator, a plug ferrule for an optical connector from one side opening, and the other side. In the optical receptacle having a sleeve that is inserted and fixed in a through-hole formed in the holder, the opening of the through-hole formed in the holder is closed with a polarizer made of a plate-like body capable of transmitting light, The tip of the plug ferrule can be brought into contact with one surface of the polarizer, and the optical surface of the Faraday rotator is bonded and fixed to the other surface.

  With respect to these inventions, the plate-like body may be fixed to the other end portion of the sleeve so that the opening thereof is closed, and further, the plate-like body is provided on the inner periphery of the other end portion of the sleeve. You may form the level | step-difference part which engages.

  In addition, the plate-like body is formed in a wedge shape, one surface is parallel to the opening surface of the one opening of the through hole of the holder, and the other surface is the opening of the other opening of the through hole. An inclined surface that is inclined with respect to the surface may be provided, and a convex support portion that supports the outer periphery of the plug ferrule at multiple points may be formed on the inner periphery of the sleeve.

  The optical module of the present invention includes a case having an optical element capable of entering light into an optical isolator of an optical receptacle with an optical isolator.

  As described above, according to the optical receptacle with an optical isolator and the optical module of the present invention, since the conventional fiber stub can be omitted, the reflection return required for a high-performance semiconductor laser as in the past is required. Light can be blocked, and a space necessary for an electric circuit for high-speed modulation can be secured. Thereby, an optical receptacle with an optical isolator having a short overall length can be realized.

  In addition, since the fiber stub is not used, the number of components is reduced, and an optical receptacle with an optical isolator that simplifies the manufacturing process at low cost can be realized.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a cross-sectional view showing an embodiment of an optical receptacle with an optical isolator of the present invention (hereinafter sometimes simply referred to as “optical receptacle”), and FIG. 2 is a cross-sectional view of an optical module using the optical receptacle.

  The optical receptacle 5 of the present invention is mainly composed of an optical isolator 9 and a sleeve 3 accommodated in the holder 4.

  The optical isolator 9 is a laminate type optical isolator configured by bonding each optical surface of the Faraday rotator 7 between two polarizers 6a and 6b, and the polarizer 6b serving as one optical surface of the polarizer 6b. The surface and the plate-like body 10 are bonded and fixed, and a cylindrical magnet 8 is disposed around the optical isolator 9 in order to apply a magnetic field to the Faraday rotator 7. In addition, an antireflection film is applied to the optical surface of the polarizer 6 a that is the other optical surface of the optical isolator 9.

  The polarizers 6a and 6b are reflective polarizations that use a diffraction grating or the like in addition to a polarizer that absorbs a polarization component perpendicular to the transmission polarization direction, such as a type in which dielectric particles are included in a glass substrate or a dielectric layered type. A birefringent crystal that shifts the optical path and the optical element can also be used. Further, the Faraday rotator 7 used in the optical isolator 9 can be configured as a Bi-substituted garnet or YIG garnet added with Tb, Gd, or Ho, or a self-bias type that does not require a magnet.

  The holder 4 has a storage portion 41 into which the sleeve 3 is press-fitted, and is formed in a bottomed cup shape. Further, a through hole 40 is formed in the approximate center of the bottom surface of the storage portion 41. Further, a flange portion 42 is formed on the outer periphery of the end portion of the holder 4 so as to be joined to a case 13 having a light source to be described later. Since the holder 4 is often welded to the case 13 that houses the optical element 11 shown in FIG. 2 as an optical module, a material that can be welded such as stainless steel, copper, iron, nickel, etc. is used. Stainless steel is used in consideration of the properties and weldability. Further, gold plating or the like may be applied to the outer surface in consideration of adhesion with solder.

  Further, the through hole 40 formed in the holder 4 is closed by the plate-like body 10 through which light can be transmitted, and the tip 20 of the plug ferrule 2 can be brought into contact with the surface on one side of the plate-like body 10, and The optical surface of the optical isolator 9 is bonded and fixed to the other surface. In order to close and fix the plate-like body 10, there are methods such as fixing with a brazing material such as solder or silver, or low melting point glass.

  Examples of the material of the plate-like body 10 include inorganic materials such as glass and sapphire, and resin materials such as acrylic, polymethyl methacrylate (PMMA), and polyolefin. However, the material is not limited to these as long as the material can transmit light. In particular, it is preferable to use an inorganic material because it can be used at a low cost and the durability is maintained even when the contact of the plug ferrule 2 is repeated.

  The sleeve 3 holds an optical connector plug ferrule 2 having an optical fiber 1 made of quartz glass or the like from one side opening, and the other side from one side opening of a through hole 40 formed in the holder 4 described above. It is configured to be inserted and fixed. A material such as zirconia, alumina, or copper is used as the material of the sleeve 3, but a zirconia ceramic material is currently used mainly considering wear resistance. The surface roughness of the inner diameter of the sleeve 3 is preferably Ra 0.2 μm or less in consideration of insertability. The outer diameter of the ferrule 2 of the fiber stub 1 and the inner diameter tolerance of the sleeve 4 are preferably ± 1 μm or less in order to obtain a low connection loss. The inner diameter of the sleeve 4 is desirably designed to be 0.98 N or more in order to securely hold the fiber stub 1.

  FIG. 2 is a cross-sectional view showing another embodiment in which the optical module 50 is configured using the optical receptacle 5 with an optical isolator of the present invention, and a case 13 in which the flange portion 42 of the holder 4 includes the semiconductor laser 11 and the lens 12. Are formed by joining.

  The optical connector generally uses a spring structure, and is structured so as to continuously apply a constant load to the tips of the optical fiber 1 and the optical connector plug ferrule 2, so that the conventional structure is brought into contact with the end face of the fiber stub. Thus, the optical fiber 1 and the optical connector plug ferrule 2 are fixed.

  However, the structure of the present invention does not have a fiber stub, and positioning of the optical connector plug ferrule 2 is performed by abutting against the plate-like body 10. The plate-like body 10 is fixed with solder, brazing material or low melting point glass so as to be closed and fixed, so that it can be sufficiently fixed even when a load is applied from the optical connector plug ferrule 2.

  The optical module 50 includes the holder 4 and the case so that the optical signal emitted from the semiconductor laser 11 passes through the lens 12 and the optical isolator 9 and is coupled to the core of the optical fiber 1 of the optical connector plug ferrule 2. 13 is assembled and adjusted.

  By the way, when a fiber stub having a conventional structure is provided, the core of the optical fiber 1 located at the center of the optical connector plug ferrule 2 is directly connected to the core of the fiber stub optical fiber. Although very small, according to the configuration of the present invention, it is unlikely that the end face of the optical fiber 1 of the optical connector plug ferrule 2 and the plate-like body 10 are completely in contact with each other, and a reflection of several percent occurs. End up. However, even for such reflected return light, the optical isolator 9 is directly joined to the plate-like body 10 so that the reflected light from the plug ferrule 2 can be cut off immediately, so that it does not return to the semiconductor laser 11 and the light Does not affect output fluctuations.

  In addition, when the loss caused by reflection is assembled at a position where it is coupled to the optical module 50, the optical signal that has passed through the lens 12 and the optical isolator 9 is reduced to a spot size of about 10 μm near the end face of the optical fiber 1. As a result, a position variation of only a few μm occurs, leading to a variation in light output.

  For this reason, a semiconductor laser 11 is generally used which can obtain an output capable of satisfying a desired output with a coupling of 40 to 60%. Since it is constructed so as to reduce the fluctuation of the light output with respect to the position fluctuation by increasing the spot size in the vicinity, it can be said that the degree of loss due to reflection is sufficiently small compared to this.

  In addition, since the reflected light from the optical surface of the polarizer 6a, which is one optical surface of the optical isolator 9, returns to the semiconductor laser 11 through the lens 12, it is preferable to apply an antireflection film. .

  As described above, according to the optical receptacle 5 with an optical isolator of the present invention, an optical isolator for blocking reflected return light required for a high-performance semiconductor laser is provided, and a necessary space for an electric circuit for high-speed modulation is provided. The total length that can be secured can be shortened. It also serves as a hermetically sealed structure to prevent the ingress of moisture contained in the outside air, and at the same time realizes high reliability of the optical module.

  FIG. 3 is a cross-sectional view showing another embodiment of an optical receptacle with an optical isolator according to the present invention. The difference from FIG. 1 is that a plate-like body 10 is formed on a wedge-like plate-like body 101. In the shape body 101, one side surface is a surface parallel to the opening surface of the one side opening of the holder 4, and the other side surface of the plate-like body 101 is an inclined surface inclined with respect to the surface of the other side opening. is there.

  As described above, by making the surface to which the optical isolator 9 is bonded as the wedge-shaped plate 101 into an inclined inclined surface, the reflected return light generated by the polarizer 6a which is one optical surface of the optical isolator 9 is transmitted to the semiconductor laser. You can easily prevent returning. For this reason, an antireflection film applied to the surface of the polarizer 6a is unnecessary, and the cost can be reduced.

  FIG. 4 is a cross-sectional view showing another embodiment of the optical receptacle with an optical isolator of the present invention. The difference from FIG. 1 is that the plate-like body 10 that closes the opening of the through hole 40 formed in the holder 4 is light-transmitted. This is a point constituted by the polarizer 6 b of the isolator 9. Thus, another optical polarizer 6a and one optical surface of the Faraday rotator 7 are bonded together, and the other optical surface of the Faraday rotator 7 is bonded and fixed to the polarizer 6b to fix the optical isolator. 9 can be configured, the number of components to be configured can be reduced, and the cost can be further reduced.

  FIG. 5 is a cross-sectional view showing another embodiment of an optical receptacle with an optical isolator of the present invention, which has a stepped portion 103 that engages a plate-like body 10 at the other end portion of the sleeve 3, and has an opening. Is fixed so as to be closed. Thereby, since the joining area of the plate-shaped body 10 and the sleeve 3 can be increased, durability can be improved with respect to the load caused by the contact of the plug ferrule 2. In addition, as described above, it is preferable to select an inorganic material as the material of the plate-like body 10, and since the zirconia ceramic material is also used for the sleeve 3 in consideration of wear resistance, these should be joined together. Thus, the difference in linear expansion coefficient can be reduced, and even if the bonding area is increased, the influence of expansion and contraction due to temperature change can be reduced.

With this structure, it is possible to realize an optical module having an airtight sealing structure and having extremely high reliability against stress due to temperature change.

  FIG. 6 is a side view showing an embodiment in which a multi-point supporting precision sleeve is used as the sleeve 3 of the optical receptacle with an optical isolator of the present invention. FIG. 6 shows a cross-sectional view of the optical receptacle 5 with an optical isolator shown in FIG. 1 when the sleeve 3 is changed when viewed from the AA direction, and a plurality of ridges 3 b are formed on the inner peripheral surface of the sleeve 3. By using a multi-point support sleeve provided with an air hole between the ridges 3b.

  Since the sleeve 3 is fitted with the optical connector plug ferrule 2 with very high accuracy, when the optical connector plug ferrule is inserted, there is a possibility that there is no way for the compressed air to escape. With this structure, the compressed air when the optical connector plug ferrule 2 is fitted can be released smoothly, and the optical connector plug ferrule can be stably fixed.

  In the following, the optical receptacle 5 with an optical isolator is prototyped based on the embodiment of the present invention shown in FIG. 1, and the coupling efficiency between the optical connector plug ferrule 2 and the semiconductor laser 11 is measured and shown for comparison. An optical receptacle 22 with an optical isolator is manufactured on the basis of the conventional configuration shown in FIG.

  In the optical receptacle 5 with an optical isolator based on the embodiment of the present invention shown in FIG. 1, the optical receptacle is composed of a precision sleeve 3 for holding the optical connector plug ferrule 2 and a holder 4 for holding the sleeve 3. 5 is configured. The optical receptacle 5 was for SC connector, zirconia was used for the precision sleeve 3, and stainless steel was used for the holder 4.

The plate-like body 10 was fixed to the holder 4 by soldering glass whose side surface was gold-plated. About the airtight sealing structure of this part, the helium leak test was done and it confirmed that the ^density of 1 * 10 < ^-9 > Pa * m < ³ > / sec or less was stably obtained by all the samples.

  An optical isolator 9 composed of the polarizers 6 a and 6 b and the Faraday rotator 7 is bonded and fixed to the plate-like body 10, and a cylindrical magnet 8 is disposed around the optical isolator 9 in order to apply a magnetic field to the Faraday rotator 7. ing. The optical isolator 9 is a polarization-dependent type and is cut into a rectangular shape, and the cylindrical magnet 8 is a ring-shaped samarium cobalt magnet.

  Then, as shown in FIG. 2, after the optical connector plug ferrule 2 is inserted into the optical receptacle 5 with an optical isolator, the light from the semiconductor laser 11 is condensed by the lens 12, and the optical connector plug ferrule 2 is collected. The optical fiber 1 was coupled. As a result, the length of the precision sleeve 3 was 6.8 mm, the length of the magnet 8 was 1.5 mm, and the total length was 8.3 mm. FIG. 7 shows the result of measuring the coupling efficiency.

  As a comparative example, a conventional optical receptacle with an optical isolator shown in FIG. 8 was prototyped. As a result, the length of the receptacle 22 was 10.5 mm, the length of the sleeve 19 was 6.8 mm, the length of the magnet 27 was 1.5 mm, and the total length was 12 mm. Similarly, the results of measuring the coupling efficiency are shown in FIG.

  Each of the measured samples is 45 samples, but all the optical receptacles 5 with an optical isolator according to the embodiment of the present invention can obtain a coupling efficiency of about 60%, and the coupling efficiency equivalent to that of the conventional optical receptacle 22 with an optical isolator is obtained. Has been obtained.

  It was also confirmed that the optical module using the optical receptacle 5 with an optical isolator according to the present invention can be shortened while keeping the coupling efficiency constant.

It is sectional drawing which shows one Embodiment of the optical receptacle with an optical isolator of this invention. It is sectional drawing which shows the optical module using the optical receptacle with an optical isolator of this invention. It is sectional drawing which shows other embodiment of the optical receptacle with an optical isolator of this invention. It is sectional drawing which shows other embodiment of the optical receptacle with an optical isolator of this invention. It is sectional drawing which shows other embodiment of the optical receptacle with an optical isolator of this invention. It is a side view which shows other embodiment of the optical receptacle with an optical isolator of this invention. It is a figure which shows the result of having measured the coupling efficiency of the plug ferrule for optical connectors and a semiconductor laser in this invention and the optical receptacle with a conventional optical isolator. It is sectional drawing which shows the conventional receptacle type optical module with an optical isolator. It is sectional drawing which shows the optical receptacle type | mold optical module with the conventional airtight structure.

Explanation of symbols

1: optical fiber 2: optical connector plug ferrule 3: sleeve 4: holder 5: optical receptacles 6a, 6b: polarizer 7: Faraday rotator 8: cylindrical magnet 9: optical isolator 10: plate 11: semiconductor laser 12: lens 13: case 14: optical fiber 15: optical connector plug ferrule 16: optical fiber 17: ferrule 18: fiber stub 19: sleeve 20: stub holder 21: sleeve case 22: optical receptacle 23: semiconductor laser 24: lens 25 : Case 26: Optical isolator 27: Cylindrical magnet 28: Dam 29: Sealing material 40: Through hole 41: Storage part 42: Flange part 50: Optical module 101: Plate-like body 102: Step

Claims (7)

An optical isolator configured by laminating the optical surfaces of a polarizer and a Faraday rotator, and a plug ferrule for an optical connector from an opening on one side, and the other side being inserted and fixed in a through hole formed in the holder. In an optical receptacle having a sleeve, the opening of the through-hole formed in the holder is closed with a plate-like body capable of transmitting light, and the tip of the plug ferrule abuts on one surface of the plate-like body An optical receptacle with an optical isolator, which is possible and has an optical surface of the optical isolator bonded and fixed to the other surface. An optical isolator configured by laminating the optical surfaces of a polarizer and a Faraday rotator, and a plug ferrule for an optical connector is held from an opening on one side, and the other side is inserted and fixed in a through hole formed in the holder. In the optical receptacle having a sleeve, the opening of the through hole formed in the holder is closed with a polarizer made of a plate-like body capable of transmitting light, and the tip of the plug ferrule is formed on one surface of the polarizer. , And the optical surface of the Faraday rotator is bonded and fixed to the other surface of the optical receptacle with an optical isolator. 3. The optical receptacle with an optical isolator according to claim 1, wherein the plate-like body is fixed so that the opening is closed at the other end portion of the sleeve. 4. The optical receptacle with an optical isolator according to claim 3, wherein a step portion for engaging the plate-like body is formed on the inner periphery of the other end portion of the sleeve. The plate-like body is formed in a wedge shape, one surface is parallel to the opening surface of one opening of the through hole of the holder, and the other surface is an opening surface of the other opening of the through hole. The optical receptacle with an optical isolator according to claim 1, wherein the optical receptacle is an inclined surface inclined with respect to the optical isolator. 6. The optical receptacle with an optical isolator according to claim 1, wherein a convex support portion for supporting the outer periphery of the plug ferrule at multiple points is formed on the inner periphery of the sleeve. An optical module comprising a case having an optical element capable of entering light into the optical isolator of the optical receptacle with an optical isolator according to claim 1.

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