JP2008225510A - Optical module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical module which is excellent in versatility and cost reduction since it can be connected to a plug of a commercially available optical fiber connector even without using exclusive components and can be optically coupled to an optical fiber with high efficiency. <P>SOLUTION: The optical module 41 of the present invention is provided with a module main body 42 and an optical element 81. The module main body 42 has such a shape and dimension that coupling to the plug 21 of an optical fiber MT connector is made possible by using a guide pin 31 used exclusively for the MT connector and a clamp spring 36 used exclusively for the MT connector. The optical element 81 is provided on the module main body 42 and optical axis alignment is performed when the plug 21 is coupled to the module main body 42 by insertion of the guide pin 31. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an optical module that has a photoelectric conversion function and is characterized by a connection structure with an optical fiber connector, a ceramic substrate used as a component of such an optical module, and a coupling structure between an optical module and a plug of an optical fiber connector It is about.

  In recent years, with the development of information communication technology represented by the Internet and the dramatic improvement in the processing speed of information processing apparatuses, there is an increasing need for transmitting and receiving large-capacity data such as images. An information transmission speed of 10 Gbps or higher is desirable to exchange such a large amount of data freely through an information communication facility, and great expectations are placed on optical communication technology as a technology that can realize such a high-speed communication environment. On the other hand, in recent years, it has been desired to increase the speed of signal transmission over a relatively short distance, such as connection between wiring boards in a device or connection between LSI chips in a wiring board. For this reason, it is considered that the transition from the conventional metal cable or metal wiring to the optical transmission using an optical fiber or an optical waveguide is ideal.

  In optical transmission using an optical fiber or the like as a signal transmission path, an optical element that converts an optical signal into an electrical signal or an optical element that converts an electrical signal into an optical signal is usually used. As a structure for connecting such an optical element and an optical fiber, for example, a technique using a guide pin and a clamp spring has been conventionally proposed (for example, see Patent Document 1). The apparatus described in Patent Document 1 includes a flat package (an optical connector connecting part) that accommodates an optical element or an LSI chip, and a flat optical fiber connector provided at the tip of a multi-core optical fiber. Yes. The optical fiber connector is stacked on the upper surface of the package. A guide pin hole for alignment is formed in the package and the optical fiber connector. Then, by inserting the guide pin into each guide pin hole and fastening with a clamp spring, the package and the optical fiber connector are detachably fixed to the wiring board in the vertical direction. In this state, the optical element and the optical fiber connector are optically coupled.

Apart from this, there has been proposed an optical connector connecting component in which an optical path orthogonal conversion optical waveguide is provided in a structure similar to a so-called MT connector plug (ferrule) (see Non-Patent Document 1, FIG. 13). An optical element 302 is mounted face-up on the wiring board 301 through bumps, and the optical connector connecting component 303 is fixed to the upper surface side of the optical element 302 with an adhesive 304 or the like. The MT connector plug 306 provided at the distal end of the multi-core optical fiber 305 is disposed in contact with the distal end surface of such a component 303. Then, the MT connector plug 306 and the optical connector connection component 303 are detachably fixed to the wiring board 301 in a horizontal direction by fastening with a clamp spring 307 dedicated to the MT connector.
JP 2003-207694 A (FIG. 1 etc.) 5th Electronic SI Research Results Report Meeting (February 26, 2004) Abstracts of Lectures, page 86, lower column

  However, since the package (optical connector connecting part) in the prior art described in Patent Document 1 is flat, it can be connected to a plug of a general commercially available optical fiber connector represented by an MT connector by a normal method. However, there is a drawback of poor versatility. Therefore, in order to realize the connection between the package and the optical fiber, it is necessary to separately manufacture a dedicated plug in accordance with the size and shape of the package. Moreover, in order to fix the dedicated optical fiber connector plug to the package, it is also necessary to separately manufacture a dedicated clamp spring and a dedicated guide pin. That is, there is a disadvantage that general-purpose parts cannot be used well for connection and are not suitable for cost reduction.

  In the case of the prior art described in Non-Patent Document 1, as shown in FIG. 13, the optical element 302 is provided not on the optical connector connecting component 303 side but on the wiring board 301 side. Therefore, it is difficult to align the optical axes of the optical element 302 and the multi-core optical fiber 305 when fixing the optical connector connecting component 303. Therefore, there is a drawback that structurally high optical coupling efficiency cannot be achieved and light transmission loss tends to increase.

  The present invention has been made in view of the above-mentioned problems, and its purpose is that it can be connected to a plug of a commercially available optical fiber connector without using a dedicated component, so that it is excellent in versatility and cost, and has high efficiency. An optical module that can be optically coupled to an optical fiber is provided. Another object of the present invention is to provide a ceramic substrate for an optical module suitable for realizing the above optical module. Still another object of the present invention is to provide a coupling structure between an optical module and a plug of an optical fiber connector, which is excellent in versatility and cost and has high optical coupling efficiency.

  As a first means for solving the above-mentioned problem, the shape and size of the optical fiber MT connector can be coupled to the plug of the optical fiber MT connector using a guide pin dedicated to the MT connector and a clamp spring dedicated to the MT connector. There is provided an optical module comprising: a module main body; and an optical element that is provided in the module main body and is optically aligned when the plug and the module main body are coupled by inserting the guide pin.

  Therefore, according to the above means, when the plug and the module main body are mechanically coupled by inserting the guide pins, the optical axes of the optical fiber and the optical element are also aligned. For this reason, although it is a comparatively simple method, an optical fiber and an optical element can be optically coupled with high efficiency. Further, if the module body is set to the above shape and dimensions, it is possible to connect the MT connector plug with the MT connector dedicated guide pin and the MT connector dedicated clamp spring as they are. Therefore, an optical module having excellent versatility and cost can be realized.

  As a second means for solving the above-mentioned problems, a plug-guide pin-plug coupling method is used by using a guide pin dedicated to the connector and a clamp spring dedicated to the connector for the plug of the optical fiber connector. A module main body having a shape and size that can be coupled, and an optical element that is provided in the module main body and that is optically aligned when the plug and the module main body are coupled by insertion of the guide pin. There is an optical module. The module body in the means has a shape and size that can be coupled to the plug of the optical fiber connector by a clamp spring fastening method using a guide pin dedicated to the connector and a clamp spring dedicated to the connector. There may be.

  Therefore, according to the above means, when the plug and the module main body are mechanically coupled by inserting the guide pins, the optical axes of the optical fiber and the optical element are also aligned. For this reason, although it is a comparatively simple method, an optical fiber and an optical element can be optically coupled with high efficiency. In addition, if the module body is set to the shape and dimensions described above, a commercially available guide pin dedicated to the optical fiber connector and a clamp spring dedicated to the optical fiber connector are used as they are to connect to the plug dedicated to the optical fiber connector. Can be achieved. Therefore, an optical module having excellent versatility and cost can be realized.

  The “optical fiber connector” is a component used when connecting optical fibers, and specific examples thereof include an optical fiber MT connector. The “optical fiber MT connector” refers to an F12 type multi-core optical fiber connector specified in JIS C 5981 established in 1993 and revised in 1998. This standard number is based on JIS C 5982 and defines a clamp spring fastening structure and a connector of a plug (plug) -guide pin-plug coupling system aligned with a guide pin. As an equivalent international standard corresponding to JIS C 5981, there is IEC 60874-16 revised in 1994.

  The module body constituting the optical module has a shape and size that can be coupled to a plug of the optical fiber MT connector using a guide pin dedicated to the MT connector and a clamp spring dedicated to the MT connector. That is, it is preferable that the module main body basically has substantially the same shape and dimensions as the plug (also called ferrule) of the optical fiber MT connector. More specifically, the module main body may be formed in a substantially rectangular parallelepiped shape like the plug of the optical fiber MT connector. Here, in the plug of the optical fiber MT connector, the dimension along the guide pin insertion direction (X-axis direction for convenience) is defined as 8.0 mm. The dimension along the optical fiber alignment direction (for convenience, the Y-axis direction) is defined as 6.4 mm to 7.0 mm, and the direction orthogonal to the X-axis direction and the Y-axis direction (for convenience, the Z-axis direction). )) Is defined as 2.5 mm to 3.0 mm. In order to perform fastening using a clamp spring dedicated to the MT connector, the dimension in the X-axis direction is particularly important. In view of this, the dimension of the module main body in the X-axis direction, in other words, the dimension from the front end surface to the rear end surface of the module main body is preferably set to 8.0 mm ± 0.3 mm, particularly 8.0 mm ± It is good to set to 0.1 mm. The reason is that the allowable value of the dimension along the X-axis direction of the plug of the optical fiber MT connector is defined as 8.0 mm ± 0.1 mm in JIS C 5981. The dimension of the module main body in the Y-axis direction is preferably set to, for example, 6.0 mm to 10.0 mm, and particularly preferably 6.4 mm to 7.0 mm. The dimension of the module body in the Z-axis direction is preferably set to, for example, 2.0 mm to 5.0 mm, particularly preferably 2.5 mm to 3.5 mm.

  The guide pin dedicated to the MT connector refers to a component that aligns the optical axes of the two plugs by being inserted into the guide pin hole of the plug. Such a guide pin is made of stainless steel and has a length of 10.8 mm or more and a diameter of about 0.7 mm. The clamp spring dedicated to the MT connector refers to a coupling component that applies a pressing force to the two plugs and couples them. Such a clamp spring is formed of an elastic metal material such as stainless steel, and the free length between the pair of sandwiching portions is defined to be 15.7 mm or less.

  The module main body has a front end surface and a rear end surface. The front end surface of the module main body is disposed to face the front end surface on the plug side, and two guide pin holes into which guide pins can be inserted are formed to be spaced apart from each other. On the other hand, the rear end surface of the module main body is positioned on the side opposite to the front end surface and is pressed to the plug side by a clamp spring. The reason for providing the guide pin hole at this position is as follows. That is, the plug-side guide pin hole is formed in the plug tip surface (that is, the exposed surface of the optical fiber tip), and the module body-side guide pin hole needs to be arranged on the surface facing it. The module main body side guide pin holes are preferably formed so as to correspond to the positions of the plug side guide pin holes. Here, in JIS C 5981, the inner diameter of the plug-side guide pin hole is defined as 7.0 mm ± 0.001 mm, and the pitch of the plug-side guide pin hole is defined as 4.6 mm ± 0.003 mm. Therefore, in order to achieve reliable optical axis alignment, the inner diameter of the module body side guide pin hole is set to 7.0 mm ± 0.001 mm, and the pitch of the module body side guide pin hole is 4.6 mm ± 0.003 mm. It is preferable to set to.

  The optical module includes an optical element (such as a light-emitting element or a light-receiving element) that is optically aligned when the plug and the module body are coupled by inserting a guide pin. Here, the light emitting element refers to an optical element having a light emitting portion. Specific examples thereof include a light emitting diode (LED), a semiconductor laser diode (LD), and a surface emitting laser (Vertical Cavity Surface). Emitting Laser (VCSEL). The light emitting element has a function of converting an input electrical signal into an optical signal and then emitting the optical signal from a light emitting unit toward a predetermined portion. On the other hand, the light receiving element refers to an optical element having a light receiving portion, and specific examples include a pin photodiode (pin PD), an avalanche photodiode (APD), and the like. The light receiving element has a function of making an optical signal incident on the light receiving unit, converting the incident optical signal into an electric signal, and outputting the electric signal. Examples of suitable materials used for the optical element include Si, Ge, InGaAs, GaAsP, and GaAlAs.

  In this case, the optical element is preferably provided inside the optical module so as not to be exposed from the outer surface of the optical module. This is because the optical device can be reliably protected and can contribute to the improvement of reliability as compared with the configuration in which the optical device is exposed on the outer surface of the optical module.

  In addition to the optical element, the module body may be provided with at least one of a semiconductor integrated circuit element for driving the optical element and a semiconductor integrated circuit element for amplifying the optical signal, for example. That is, when the optical element is a light emitting element, the module body may be provided with a light emitting element and a semiconductor integrated circuit element (so-called driver IC) for driving the light emitting element. When the optical element is a light receiving element, the module main body may be provided with a light receiving element and a semiconductor integrated circuit element for optical signal amplification (so-called receiver IC). With such a configuration, for example, the conduction distance can be shortened and the operation speed can be increased compared to a case where a semiconductor integrated circuit element is provided outside the optical module and the optical element is electrically connected to the optical module. . Of course, in the case of an optical module having both a light emitting element and a light receiving element, the module body may be provided with both a semiconductor integrated circuit element for driving the optical element and a semiconductor integrated circuit element for amplifying the optical signal.

  In this case, it is preferable that the semiconductor integrated circuit element for driving the optical element or for amplifying the optical signal is provided inside the optical module so as not to be exposed from the outer surface of the optical module. This is because the semiconductor integrated circuit element can be reliably protected and can contribute to improvement in reliability as compared with the structure in which the semiconductor integrated circuit element is exposed on the outer surface of the optical module.

  Further, the module body may be provided with electronic components and elements other than the optical element and the semiconductor integrated circuit element. Specific examples of the electronic component include a chip transistor, a chip diode, a chip resistor, a chip capacitor, and a chip coil. These electronic components may be active components or passive components. Specific examples of the element include a thin film transistor, a thin film diode, a thin film resistor, a thin film capacitor, and a thin film coil. These elements may be active elements or passive elements. In this case, by providing a chip capacitor or a thin film capacitor, it is possible to reduce the resistance and the inductance, so that it is easy to realize high performance of the optical module.

  It is preferable that the module main body is mainly composed of a material having higher heat dissipation than the resin material used for the plug (that is, a material having high thermal conductivity). The reason is described below. Although heat is generated when the optical element is operated, the resin material used for the plug is generally not very heat-dissipating, so the heat cannot be efficiently dissipated to the outside, which causes the operation to become unstable. It becomes. On the other hand, if the module main body is mainly composed of a high heat dissipation material, heat can be efficiently dissipated to the outside and stable operation can be obtained. Preferable examples of the material having higher heat dissipation than the resin material used for the plug include inorganic materials such as metals and ceramics.

  It is preferable that the module main body is mainly composed of a ceramic (that is, a ceramic substrate) formed in a substrate shape. This is because heat can be efficiently dissipated to the outside if the module body is mainly composed of such a structure. Specific examples of suitable ceramic substrates in this case include alumina substrates, beryllia substrates, mullite substrates, aluminum nitride substrates, silicon nitride substrates, boron nitride substrates, silicon carbide substrates and the like. Those listed here are particularly excellent in heat dissipation.

  More preferably, the module body is mainly composed of a ceramic wiring substrate, and particularly preferably is composed mainly of a multilayer ceramic wiring substrate. Since such a wiring board is provided with a conductor layer and an insulating layer, electrical connection between the optical element and other components can be easily achieved using the conductor layer.

  The ceramic substrate has a substrate main surface, a substrate back surface located on the opposite side of the substrate main surface, and a plurality of side end surfaces perpendicular to the substrate main surface. A hole constituting at least a part of the guide pin hole is formed in one of the plurality of side end surfaces. More preferably, a filling recess is formed in a side end surface perpendicular to the main surface of the ceramic substrate, a filler made of a material having better workability than the ceramic substrate is filled in the filling recess, and the filler is guided. It is preferable to form a precision machined hole that constitutes at least a part of the pin hole. With such a configuration, since the guide pin hole is a precision machined hole, the optical axis of the optical fiber and the optical element can be more accurately aligned, and the optical coupling efficiency can be reliably improved. . Ceramics have the advantage of being excellent in heat dissipation and dimensional stability, but have the disadvantage of being hard and inferior in workability. For this reason, it is difficult to directly process a ceramic substrate to provide a precision processing hole, which leads to high costs. On the other hand, a precision drilled hole formed by subjecting a filler made of an easily processable material to precision drilling can be obtained relatively easily and at low cost. In addition, as a specific method for forming the precision processed hole, there are a drilling process, a punching process, a laser processing, and the like, but in consideration of cost and the like, a drilling process using a precision drill is most preferable.

  As the filler, it is preferable to select a resin material, a metal material, a glass material, or the like having a lower hardness than the ceramic substrate and good workability, and it is particularly preferable to select a resin material. This is because the resin material generally has a lower hardness than the ceramic material, so that labor and cost required for processing can be reduced. Moreover, since resin materials are generally cheaper than ceramic materials, they are also suitable for cost reduction.

  The optical element and the semiconductor integrated circuit element may be disposed on the same surface side of the ceramic substrate or may be disposed on different surface sides. When the latter configuration is employed, for example, the optical element is preferably disposed on the side end face side of the ceramic substrate, and the semiconductor integrated circuit element is preferably disposed on the substrate main surface side of the ceramic substrate. According to this configuration, since the light emitting surface or the light receiving surface of the optical element faces the X-axis direction, it is possible to achieve optical coupling with an optical fiber without performing optical path conversion. For example, a flexible substrate may be used in order to conduct between the optical element and the semiconductor integrated circuit element arranged on different surfaces.

  In the module body, a metal body may be provided on a surface other than the front end surface and the rear end surface, for example, on the upper end surface. With such a metal body, heat dissipation is further improved, so that heat of the optical element and the semiconductor integrated circuit element can be efficiently dissipated to the outside. Therefore, it becomes easy to achieve operation stabilization of the optical module. In addition, since it is possible to use a highly functional semiconductor integrated circuit element, it is easy to achieve an improvement in the performance of the optical module. Furthermore, the optical element and the semiconductor integrated circuit element are shielded from external electromagnetic waves, and as a result, the operation of the optical module is stabilized. Examples of the material of the metal body include copper, copper alloy, iron, nickel, iron-nickel alloy, and aluminum. The metal body is formed using, for example, a plate shape, a foil shape, or a layer shape using such a material. The metal body may be a bump connected to a substrate side on which the optical module is to be mounted. With such a heat dissipation bump, the heat of the optical element and the semiconductor integrated circuit element can be efficiently dissipated to the substrate side.

  In the module main body, a plurality of electrical connection terminals may be provided on a surface other than the front end surface and the rear end surface, for example, on the lower end surface. According to this configuration, electrical connection with the substrate side on which the optical module is to be mounted can be easily achieved. The form of the electrical connection terminal is not particularly limited, and examples thereof include bumps, pads, leads, and the like.

  The optical module may be provided with a microlens array which is a component having a light collecting function. When there is a microlens array, light transmission loss is reduced by collecting light. When a microlens array is employed, a spacer member for adjusting the focal length may be further provided.

  As another means for solving the above-described problem, a guide pin dedicated to the connector is used in a state where the exposed end of the fiber end of the plug is in contact with the end of the end of the optical fiber connector. An optical module comprising: a connectable module main body; and an optical element that is provided in the module main body and is optically aligned when the plug and the module main body are combined by inserting the guide pins. There is. Further, as another means, there is a coupling structure of an optical module in which an optical element is provided in the module body and a plug of an optical fiber connector, and the exposed surface of the fiber end of the plug and the front end surface of the optical module are butted together. An optical module and a plug of an optical fiber connector, wherein the plug and the optical module are coupled and optical axes are aligned by inserting guide pins into the plug and the optical module in a state where There is a combined structure. In these means, when the plug and the optical module are coupled, it is preferable that the upper surface of the plug and the upper surface of the optical module are substantially flush with each other, whereby the overall height can be reduced. In these means, the plug and the optical module may be coupled using not only the guide pin but also a clamp spring of an optical fiber connector.

  As a means for solving the above-mentioned another problem, there is provided a ceramic substrate used in an optical module having a shape and a dimension that can be coupled to a plug of an optical fiber MT connector by using a guide pin. A side end surface perpendicular to the surface and the main surface of the substrate, a filling recess is formed in the side end surface, and the filling recess is filled with a filler made of a material that is more workable than the substrate material, There is a ceramic substrate for an optical module, in which a precision processing hole which is the guide pin hole is formed in the filler.

  In addition to being excellent in heat dissipation, dimensional stability, and cost performance, the ceramic substrate for optical modules of the above means is provided with precision processed holes on the side end surfaces. Therefore, if this ceramic substrate is used, the above excellent optical module can be easily realized.

  The ceramic substrate for an optical module, for example, a step of preparing a ceramic unsintered body having a filling recess that opens at a side end surface, a step of firing the ceramic unsintered body to form a ceramic sintered body, Producing through a step of filling a filler in the filling recess in the ceramic sintered body and a step of forming a hole in the guide pin hole by drilling the filler. Is possible. According to this manufacturing method, since the hole processing is performed in an unsintered stage, the guide pin hole can be formed relatively easily and inexpensively.

  More specifically, the ceramic substrate for an optical module is prepared by preparing a plurality of green sheets, forming a notch near the side end face, and laminating the plurality of green sheets to form an unsintered ceramic laminate. A step of forming a filling recess that opens at a side end surface by overlapping the notch, firing the green ceramic laminate to form a ceramic sintered body, Manufacturing through a step of filling the filler into the filling recess in the ceramic sintered body and a step of forming a hole in the filler to form at least a part of the guide pin hole. Is preferred.

[First Embodiment]

  Hereinafter, a first embodiment of the present invention will be described in detail with reference to FIGS.

  FIG. 1 is a schematic front view showing a state in which the optical module 41 of the present embodiment is mounted on the printed wiring board 11 and the MT connector plug 21 is connected. FIG. 2 is an exploded front view showing the printed wiring board 11, the optical module 41, the MT connector plug 21, the multi-core optical fiber 26, the guide pin 31, and the clamp spring 36. FIG. 3 is a schematic front view showing a state in which the optical module 41 is connected to the MT connector plug 21. FIG. 4 is a perspective view showing an optical module ceramic substrate 51 constituting the module main body 42. FIG. 5 is a plan view of the optical module 41. 6 is a cross-sectional view taken along line AA in FIG. 7 is a cross-sectional view taken along line BB in FIG.

  As shown in FIG. 1 and the like, a printed wiring board 11 for mounting an optical module is a so-called multilayer board having a plurality of insulating layers 15 and a plurality of conductor layers (not shown), and has a front surface 12 and a back surface 13. is doing. A plurality of pads (not shown) are formed on the surface 12 of the printed wiring board 11, and two optical modules 41 are bump-connected on these pads. The optical module 41 located on the right side in FIG. 1 is a light emitting side optical module that converts an electrical signal into an optical signal, and the optical module 41 located on the left side in FIG. 1 is a light receiving side that converts an optical signal into an electrical signal. It is an optical module. In addition to the optical module 41, the IC chip 16 and the like are similarly bump-connected to the surface 12 of the printed wiring board 11.

  2, 3, 5, 6, and 7, the optical module 41 of this embodiment includes a ceramic substrate 51, a flexible substrate 76, a lid 72 (metal body), a microlens array 73, and a spacer. A module main body 42 comprising 74 is provided. The optical module 41 has a substantially rectangular parallelepiped shape, and is designed so that the dimensions of each part are substantially the same as those of the MT connector plug 21. Specifically, the dimension of the optical module 41 in the X-axis direction (left-right direction in FIG. 6) is set to 8.0 mm. The dimension of the optical module 41 in the Y-axis direction (vertical direction in FIG. 5) is set to 7.0 mm. The dimension of the optical module 41 in the Z-axis direction (left-right direction in FIGS. 5 and 6) is set to 3.0 mm.

  As shown in FIGS. 4, 6, and 7, the ceramic substrate 51 that forms the main part of the module body 42 is a multilayer alumina wiring substrate having a plurality of ceramic insulating layers 52 and a plurality of conductor layers 57. . In the ceramic substrate 51, a through-hole conductor 58 is formed for conducting different layers of conductor layers 57. Cavities 59 are formed on the upper end surface 55 (substrate main surface) side and the lower end surface 56 side of the ceramic substrate 51, respectively. A capacitor 83 is accommodated in the cavity 59 on the lower end surface 56 side. For one optical module 41, a driver IC 82 is accommodated in a cavity 59 on the upper end surface 55 side of the ceramic substrate 51. Regarding the other optical module 41, a receiver IC is accommodated in a cavity 59 on the upper end surface 55 side of the ceramic substrate 51. Note that the gap formed in the cavity 59 may be filled with, for example, a silicone resin 84 or the like. Moreover, in order to improve heat dissipation, the gap may be filled with thermal grease.

  A flexible substrate 76 made of polyimide resin is bonded to the upper end surface of the ceramic substrate 51, and a lid 72 made of white and white is further bonded thereon. The lid 72 is a metal plate having a thickness of about 0.5 mm, and has an area substantially equal to the area of the upper end surface of the optical module 41. The driver IC 82 and the VCSEL 81 (optical element) are bump-connected to one side surface of the flexible substrate 76. These are electrically connected via a wiring pattern of the flexible substrate 76. A part of the flexible substrate 76 protrudes from the side end surface 53 and is bent at a right angle so as to be along the side end surface 53. Accordingly, the VCSEL 81 is disposed on the side end surface 53 of the ceramic substrate 51, and the light emitting surface thereof is in a state facing the X-axis direction of the optical module 41. On the other hand, since the driver IC 82 is in the cavity 59 on the upper end surface 55 side of the ceramic substrate 51, it can be grasped that the driver IC 82 is substantially disposed on the upper end surface 55 of the flexible substrate 76.

  A flat microlens array 73 made of a transparent material is attached to the side end face 53 side of the ceramic substrate 51 via a square frame spacer 74. The spacer 74 is formed of, for example, a resin material or metal material having solder heat resistance. The VCSEL 81 has a plurality of (in the present embodiment, twelve) light emitting sections, and the microlens array 73 is provided with a plurality of microlenses corresponding to these. The light emitting unit and the microlens are both arranged in a straight line along the Y-axis direction of the optical module 41.

  As shown in FIGS. 2 to 7, two filling recesses 61 having a rectangular cross section are formed in the side end face 53 of the ceramic substrate 51 of the present embodiment. The filling recesses 61 are filled with a filler 63 made of a resin material having better workability than the ceramic substrate 51. The filler 63 is formed with a precision machining hole 62 having a circular cross section. There are two precision machining holes 62, both of which are opened at the side end face 53 of the ceramic substrate 51. The precision machining holes 62 are formed corresponding to the positions of the two plug-side guide pin holes 22 in the MT connector plug 21. Accordingly, the pitch of the precision machining holes 62 is equal to the pitch of the plug-side guide pin holes 22 and is set to 4.6 mm ± 0.003 mm. The inner diameters of the precision machining holes 62 are equal to the inner diameter of the MT connector plug 21 and are set to 7.0 mm ± 0.001 mm. Further, a through hole 70 having an inner diameter of 7.0 mm ± 0.001 mm and a pitch of 4.6 mm ± 0.003 mm is formed at a position corresponding to the precision machining hole 62 in the flexible substrate 76. In the microlens array 73, through holes 85 having an inner diameter of 7.0 mm ± 0.001 mm and a pitch of 4.6 mm ± 0.003 mm are formed at positions corresponding to the precision machining holes 62.

  In the module main body 42, the precision machining hole 62 and the through holes 70 and 85 communicate with each other, and as a result, a module main body side guide pin hole 80 is formed. That is, the module main body 42 of the present embodiment is provided with two module main body side guide pin holes 80 opened at the tip end face 43. The depth of the module main body side guide pin hole 80 is about 3.0 mm in this embodiment.

  As shown in FIG. 3, the distal end surface 23 of the MT connector plug 21, that is, the surface where the distal end of the multi-core optical fiber 26 is exposed, and the distal end surface 43 of the module main body 42 are parallel and protrude from each other. Are combined. In this state, one end of the guide pin 31 is inserted and fixed in the plug-side guide pin hole 22, and the other end of the guide pin 31 is inserted and fixed in the module body-side guide pin hole 80. And the optical module 41 are mechanically coupled. At the time of such coupling, the multi-core optical fiber 26 held by the MT connector plug 21 and the VCSEL 81 of the optical module 41 are optically aligned. In the present embodiment, specifically, a guide pin “CNF125A-21” (diameter 0.699 mm) defined in JIS C 5981 is used. Further, the MT connector plug 21 and the optical module 41 are clamped and fixed using an MT connector clamp spring 36 defined in JIS C 5981. More specifically, the MT connector clamp spring 36 sandwiches the MT connector plug 21 and the optical module 41 in a state of abutting each other by a pair of sandwiching portions 37. As a result, a pressing force is applied to the rear end surface of the MT connector plug 21 and the rear end surface 44 of the optical module 41, and a reliable coupling between the two is achieved.

  As shown in FIGS. 3, 6, 7, etc., a plurality of solder bumps 75 as a plurality of electrical connection terminals are provided in an array on the lower end surface 56 of the ceramic substrate 51. The optical module 41 is electrically connected to the surface 12 of the printed wiring board 11 through these solder bumps 75.

  The general operation of the apparatus configured as described above will be briefly described.

  Electric power is supplied from the printed wiring board 11 side to the optical module 41 having a light emitting element, and the VCSEL 81 and the driver IC 82 are operable by this electric power supply. An electric signal input from the printed wiring board 11 side is first input to the driver IC 82. Then, the driver IC 82 outputs a predetermined electric signal to the VCSEL 81 via the wiring pattern of the flexible substrate 76. The VCSEL 81 converts the input electrical signal into an optical signal (laser light), and then emits the optical signal toward the distal end surface of the multi-core optical fiber 26. The emitted optical signal passes through the transparent or translucent flexible substrate 76 and is then collected when passing through the microlenses of the microlens array 73. The condensed light is incident on each core of the multi-core optical fiber 26 held by the MT connector plug 21 and travels toward the light receiving side optical module 41.

  Next, a method for manufacturing the optical module 41 will be described.

  First, the ceramic substrate 51 is manufactured by the following procedure. A raw material slurry is prepared by uniformly mixing and kneading alumina powder, organic binder, solvent, plasticizer, etc., and this raw material slurry is used to form a sheet with a doctor blade device to produce a plurality of green sheets with a predetermined thickness. Form. A predetermined portion of the green sheet is punched to form through-holes, which are filled with a metal paste (for example, tungsten paste) for through-hole conductors. At the same time, a notch that opens at the side end surface of the green sheet is formed. This notch will later constitute part of the filling recess 61. Moreover, the printing layer used as a conductor layer later is formed by printing a metal paste on the surface of a green sheet. Then, the plurality of green sheets are laminated. In that case, it arrange | positions so that notch parts may overlap. And it presses with a predetermined pressure, each green sheet is integrated, and it is set as an unsintered green sheet laminated body. Next, after performing a drying process, a degreasing process, etc. according to a well-known method, a baking process is performed at the heating temperature (for example, 1650 degreeC-1950 degreeC) which an alumina can sinter further. Thus, the green sheet laminate is sintered to form the ceramic substrate 51, and the filling recess 61 opened at the side end face 53 is formed.

  Next, with respect to 80 parts by weight of a bisphenol F type epoxy resin (“Epicoat 807” manufactured by JER) and 20 parts by weight of a cresol novolac type epoxy resin (“Epicoat 152” manufactured by JER), a curing agent (“Shikoku Kasei Kogyo Co., Ltd.” 2P4MZ-CN ") 5 parts by weight, 200 parts by weight of silica filler (" TSS-6 "manufactured by Tatsumori) treated with a silane coupling agent (" KBM-403 "manufactured by Shin-Etsu Chemical Co., Ltd.), defoaming agent (manufactured by Sannopco) "Berenol S-4") is mixed. This mixture is kneaded with three rolls to form a filler 63 for filling the filling recess 61. That is, the filler 63 of the present embodiment includes an inorganic filler in a thermosetting resin. Then, the filling material 63 is filled into the filling recess 61 by a conventionally known method (for example, a printing method), and heated at 120 ° C. for 1 hour, so that the filling material 63 is semi-cured. Here, the reason why the filler 63 is not completely cured is to perform the hole processing in the next process more easily.

  Subsequently, precision drilling using a precision drill is performed to form precision drilled holes 62 in the semi-cured filler 63. According to such a hole machining method, the guide pin hole 80 which becomes an accurate reference for optical axis alignment can be obtained easily and reliably. In addition, since the hole processing is performed on the resin material, labor and cost required for the processing can be reduced, and the cost of the optical module 41 can be reduced. Here, the surplus filler 63 protruding from the opening of the filling recess 61 may be removed by setting the ceramic substrate 51 in a surface polishing apparatus and polishing the side end face 53.

  Next, a main curing process is performed in which the ceramic substrate 51 is heated at 150 ° C. for 5 hours to completely cure the filler 63. Further, finishing is performed by a well-known method, and fine adjustment is performed so that the hole diameter of the precision machining hole 62 becomes 0.700 mm. Specifically, the accuracy required for processing at this time is ± 0.001 mm. As a result, the optical module ceramic substrate 51 is completed. The completed ceramic substrate 51 is further provided with solder bumps 75 by a conventionally known method.

  Next, a procedure for manufacturing the optical module 41 by attaching other components to the ceramic substrate 51 will be described. In this case, the flexible substrate 76 is prepared, and the VCSEL 81 and the driver IC 82 are mounted in advance on one side surface. Then, the ceramic substrate 51, the flexible substrate 76, the spacer 74, and the microlens array 73 are arranged in this order, and the guide pins 31 are inserted into the precision processing holes 62 and the through holes 70 and 85. As a result, the flexible substrate 76 and the microlens array 73 are fixed to the ceramic substrate 51 while being aligned. Next, the flexible substrate 76 is bent at a right angle, and the bent portion is bonded to the upper end surface 55 of the ceramic substrate 51 with an anisotropic conductive film. Further, a lid 72 is adhered thereon with a silver epoxy adhesive. It is also possible to electrically connect the conductor on the flexible substrate 76 side and the conductor on the ceramic substrate 51 side by means such as conductive paste, conductive film, or soldering. As a result, an optical module 41 with guide pins 31 as shown in FIG. 2 is obtained. Thereafter, the optical module 41 is soldered onto the surface 12 of the printed wiring board 11. Note that the flexible substrate 76, the spacer 74, and the microlens array 73 may be attached by the guide pins 31 after only the ceramic substrate 51 is soldered on the surface 12 of the printed wiring board 11.

  Further, a procedure for connecting the optical module 41 with guide pins 31 mounted on the printed wiring board 11 and the MT connector plug 21 will be described. Here, the MT connector plug 21 integrated with the multi-core optical fiber 26 is used. The distal end surface 23 of the MT connector plug 21 is disposed to face the distal end surface 43 of the optical module 41, and the protruding end of the guide pin 31 is inserted into the plug-side guide pin hole 22. Then, the MT connector plug 21 is brought closer to the optical module 41 side so that the distal end surface 23 of the MT connector plug 21 and the distal end surface 43 of the optical module 41 abut against each other. Next, the MT connector clamp spring 36 is mounted from above the MT connector plug 21 and the optical module 41, and the both are clamped and fixed. In this way, the pressing force of the MT connector clamp spring 36 is constantly applied to the MT connector plug 21 and the optical module 41, so that the two are reliably coupled.

  Therefore, according to the present embodiment, the following effects can be obtained.

  (1) That is, when the MT connector plug 21 and the module body 42 are mechanically coupled by inserting the MT connector guide pins 31, the optical fibers of the multi-fiber optical fiber 26 and the optical element are aligned together. . For this reason, although it is a comparatively simple method, the multi-core optical fiber 26 and the optical element can be optically coupled with high efficiency. Further, since the module main body 42 set to have substantially the same shape and size as the MT connector plug 21 is used, the MT connector dedicated guide pin 31 and the MT connector dedicated clamp spring 36 are used as they are, and the MT connector connector is used. Connection with the plug 21 is possible. Therefore, the optical module 41 excellent in versatility and cost can be realized.

  (2) In this embodiment, the module main body 42 is provided with a semiconductor integrated circuit element for driving an optical element or for amplifying an optical signal in addition to the optical element. Therefore, the conduction distance can be shortened and the operation speed is increased.

  (3) In this embodiment, the optical elements such as the VCSEL 81 and the semiconductor integrated circuit elements such as the driver IC 82 are provided so as not to be exposed from the outer surface of the optical module 41. In other words, the optical element and the semiconductor integrated circuit element are embedded in the optical module 41. Therefore, as compared with the configuration in which the optical element and the semiconductor integrated circuit element are exposed on the outer surface of the optical module 41, the optical element and the semiconductor integrated circuit element can be surely protected, and the reliability can be improved.

(4) In this embodiment, since the optical module 41 is provided with not only optical elements but also semiconductor integrated circuit elements, the total amount of heat generated is large. In addition, since the optical element and the semiconductor integrated circuit element are embedded in the optical module 41, the structure is such that heat tends to accumulate in the first place. However, since the optical module 41 is mainly composed of the ceramic substrate 51 excellent in heat dissipation and the lid 72 is provided, heat is efficiently dissipated to the outside. In addition, since some of the solder bumps 75 are heat dissipation solder bumps, heat is efficiently dissipated outside the optical module 41 through them.
[Second Embodiment]

  Next, the optical module 141 according to the second embodiment will be described in detail with reference to FIGS. FIG. 8 is a plan view of the optical module 141 of the present embodiment. 9 is a cross-sectional view taken along the line CC of FIG. Here, the description will focus on the parts that are different from the first embodiment, and the common parts will not be described in place of the same member numbers.

  As shown in FIGS. 8 and 9, in this optical module 141, the flexible substrate 76 that is a support for the VCSEL 81 and the driver IC 82 is omitted, and the VCSEL 81 and the driver IC 82 are directly bonded to the ceramic substrate 51. More specifically, the driver IC 82 is bonded to the bottom surface of the cavity 59 on the upper end surface 55 side of the ceramic substrate 51, and the VCSEL 81 is bonded to the side end surface 53 of the ceramic substrate 51. The driver IC 82 is electrically connected to the through-hole conductor 58 or the conductor layer 57. The VCSEL 81 is electrically connected to the conductor layer 57 via a bonding wire 91, for example.

And even if it is the optical module 141 of the said structure, there exists an effect similar to 1st Embodiment fundamentally. Moreover, with this structure, the number of components is reduced due to the omission of the flexible substrate 76, and it is easy to achieve cost reduction. In addition, since the thermal conductivity between the ceramic substrate 51 and the lid 72 is improved, further improvement in heat dissipation can be expected.
[Third Embodiment]

  Next, the optical module 241 according to the third embodiment will be described in detail with reference to FIGS. FIG. 10 is a plan view of the optical module 241 of the present embodiment. 11 is a cross-sectional view taken along the line DD of FIG. Here, the description will focus on the parts that are different from the first embodiment, and the common parts will not be described in place of the same member numbers.

  As shown in FIGS. 10 and 11, in this optical module 241 as well, the flexible substrate 76 that was a support for the VCSEL 81 and the driver IC 82 is omitted, and the VCSEL 81 and the driver IC 82 are directly bonded to the ceramic substrate 51. More specifically, the driver IC 82 is bonded to the bottom surface of the cavity 59 on the upper end surface 55 side of the ceramic substrate 51. Further, the VCSEL 81 is bonded to the upper surface of the thin overhanging portion 244 in the ceramic substrate 51. The driver IC 82 and the VCSEL 81 are electrically connected to the through-hole conductor 58 or the conductor layer 57. In other words, in the present embodiment, the VCSEL 81 faces the Z-axis direction (upward direction in FIG. 11) instead of the X-axis direction.

  A spacer 245 having a substantially L-shaped cross section is provided in the space above the thin overhanging portion 244, and a microlens array 247 with a 45 ° optical path conversion mirror 246 is provided on the spacer 245. A guide pin hole 251 is formed in the microlens array 247 along the Z-axis direction. Similarly, a guide pin hole 252 is formed in the thin overhanging portion 244 of the ceramic substrate 51. The guide pins 31 are inserted into the guide pin holes 251 and 252 so that the optical axes of the VCSEL 81 and the microlens array 247 are aligned.

And according to this embodiment, it is excellent in versatility and cost efficiency, and can provide the optical module 241 which can be optically coupled with the multi-core optical fiber 26 with high efficiency. Moreover, with this structure, the driver IC 82 and the VCSEL 81 need only be mounted in the same direction, so that component mounting can be performed efficiently and easily. Further, since the thermal conductivity between the ceramic substrate 51 and the lid 72 is improved by omitting the flexible substrate 76, further improvement in heat dissipation can be expected.
[Fourth Embodiment]

  Next, the optical module 261 of the fourth embodiment will be described in detail with reference to FIG. FIG. 12 is a plan view of the optical module 241 of the present embodiment. Here, the description will focus on the parts that are different from the first embodiment, and the common parts will not be described in place of the same member numbers.

  As shown in FIG. 12, since this optical module 261 is a so-called transmission / reception optical module, it includes two different types of optical elements, specifically, one VCSEL 81 and one photodiode 271. . Therefore, the optical module 261 includes not only the driver IC 82 but also the receiver IC 272 (semiconductor integrated circuit element for optical signal amplification). The driver IC 82 and the VCSEL 81 are electrically connected via the wiring pattern of the flexible substrate 76. The receiver IC 272 and the photodiode 271 are also electrically connected via another wiring pattern on the flexible substrate 76. On the upper end surface 55 side of the ceramic substrate 51, a cavity 59 for disposing the driver IC 82 and a cavity 59 for disposing the receiver IC 272 are separately formed. A conductor plating layer is formed on the inner surfaces of these cavities 59. The cavities 59 are separated from each other by a partition wall 273. With these configurations, the driver IC 82 that is the configuration on the transmission side and the receiver IC 272 that is the configuration on the reception side are electromagnetically separated. A shield member 262 is provided between the VCSEL 81 and the photodiode 271. The shield member 262 is conductor-plated on the surface of the substrate. The VCSEL 81 that is the configuration on the transmission side and the photodiode 271 that is the configuration on the reception side are electromagnetically separated by the intervention of the shield member 262. The shield member 262 may be formed by conducting conductor plating on the surface of the spacer 74.

  According to this embodiment, it is possible to provide an optical module 261 that is excellent in versatility and cost, can be optically coupled to the multi-core optical fiber 26 with high efficiency, and has high added value.

  It goes without saying that the present invention is not limited to the above-described embodiment, and can be appropriately modified and applied without departing from the scope of the invention.

  For example, the spacers 74 and 245 used in the first to third embodiments may be omitted, and in this case, the number of parts can be further reduced.

  In the third embodiment, the ceramic substrate 51, the microlens array 247, and the lid 72 are aligned and fixed by the guide pins 31. Also good.

  -In 1st-4th embodiment, although the lid 72 was provided only in the upper end surface of the module main body 42, you may make it provide this in several surfaces.

  -In 1st-4th embodiment, although the unevenness | corrugation did not exist especially in the inner wall face of the filling recessed part 61, and the internal diameter was substantially constant, you may provide an unevenness | corrugation by changing an internal diameter with a depth position. According to this configuration, the contact area between the inner wall surface of the filling recess 61 and the filler 63 is increased, and the adhesion of the filler 63 is improved. Therefore, the generation of gaps and cracks due to thermal stress concentration can be avoided, and the reliability is excellent.

  In the first embodiment, in forming the precision processed hole 62, filling of the filler 63 → semi-curing of the filler 63 (120 ° C.) → hole processing → surface polishing → main curing of the filler 63 (150 ° C.) Although the process is adopted, it is needless to say that another process may be adopted. For example, a process of filling the filler 63 → semi-curing of the filler 63 (120 ° C.) → surface polishing → main curing of the filler 63 (150 ° C.) → hole processing may be used.

  Next, the technical ideas grasped by the embodiment described above are listed below.

  (1) A module body having a shape and size that can be coupled to a plug of the optical fiber MT connector using a guide pin dedicated to the MT connector and a clamp spring dedicated to the MT connector, and exposed from the outer surface of the module body. And an optical element that is provided inside the optical module so that the optical axis is aligned when the plug and the module main body are coupled by insertion of the guide pin.

  (2) A shape and size that can be coupled to the plug of the optical fiber MT connector using a guide pin dedicated to the MT connector and a clamp spring dedicated to the MT connector, and a guide pin hole is formed in the side end surface. A module main body, and an optical element that is provided in the module main body and is optically aligned when the plug and the module main body are coupled by insertion of the guide pin, and the guide pin is inserted into the guide pin hole. Is inserted and fixed, and a part of the guide pin protrudes from the module main body.

  (3) A module body having a shape and a dimension that can be coupled by a clamp spring fastening method using a guide pin dedicated to the connector and a clamp spring dedicated to the connector to the plug of the optical fiber connector, and provided on the module body And an optical element whose optical axis is aligned when the plug and the module main body are coupled by insertion of the guide pin.

  (4) A module main body that can be coupled to a plug of an optical fiber connector using a guide pin dedicated to the connector in a state in which the exposed end face of the optical fiber in the plug is in contact with the front end face of the optical fiber connector; A light emitting element that is optically aligned when the plug and the module main body are coupled by insertion of the guide pin; and the plug and module main body that are provided in the module main body and inserted by the guide pin And a light receiving element that is aligned with the optical axis when coupled to each other.

  (5) A module main body that can be coupled to a plug of an optical fiber connector using a guide pin dedicated to the connector in a state in which the exposed end face of the optical fiber in the plug is in contact with the front end face of the optical fiber connector; A light-emitting element that is optically aligned when the plug and the module body are coupled by insertion of the guide pin, and a light-emitting element that is provided in the module body and is electrically connected to the light-emitting element A semiconductor integrated circuit device for driving; provided in the module main body; and a light receiving element that is optically aligned when the plug and the module main body are coupled by insertion of the guide pins; and provided in the module main body, An optical module comprising an optical signal amplification semiconductor integrated circuit element electrically connected to the light receiving element Lumpur.

BRIEF DESCRIPTION OF THE DRAWINGS The schematic front view which shows the state which mounted the optical module of 1st Embodiment which actualized this invention on the printed wiring board, and connected the plug for MT connectors. The exploded front view which shows a printed wiring board, an optical module, the plug for MT connectors, a multi-core optical fiber, a guide pin, and a clamp spring. The schematic front view which shows the state which connected the optical module to the plug for MT connectors. The perspective view which shows the ceramic substrate for optical modules which comprises a module main body. The top view of an optical module. Sectional drawing in the AA of FIG. Sectional drawing in the BB line of FIG. The top view of the optical module of 2nd Embodiment. Sectional drawing in the CC line | wire of FIG. The top view of the optical module of 3rd Embodiment. Sectional drawing in the DD line | wire of FIG. The top view of the optical module of 4th Embodiment. Schematic for demonstrating a prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 21 ... Plug 31 ... Guide pin 36 ... Clamp spring 41, 141, 241, 261 ... Optical module 42 ... Module main body 43 ... (optical module) front end surface 44 ... (optical module) rear end surface 51 ... Ceramic substrate 53 ... side End surface 55 ... Upper end surface as a substrate main surface 61 ... Filling recess 62 ... Precision machining hole 63 ... Filling material 72 ... Lid as metal body 75 ... Solder bump as electric connection terminal 80 ... Guide pin hole 81 ... As optical element VCSEL
82 ... Driver IC as a semiconductor integrated circuit element
271: Photodiode as an optical element 272: Receiver IC as a semiconductor integrated circuit element

Claims (13)

A module body having a shape and a dimension that can be coupled to a plug of the optical fiber MT connector using a guide pin dedicated to the MT connector and a clamp spring dedicated to the MT connector;
An optical module, comprising: an optical element provided on the module main body and having an optical axis aligned when the plug and the module main body are coupled by insertion of the guide pin.   The module body includes a front end surface in which a guide pin hole into which the guide pin can be inserted is formed, and a rear end surface that is located on the opposite side of the front end surface and is pressed toward the plug by the clamp spring. The optical module according to claim 1, further comprising:   3. The optical module according to claim 1, wherein the module body is mainly composed of a material having a higher heat dissipation property than a resin material used for the plug.   The optical module according to claim 3, wherein the module body is mainly composed of a ceramic substrate.   A filling recess is formed in a side end surface perpendicular to the substrate main surface of the ceramic substrate, and the filling recess is filled with a filler made of a material having better workability than the ceramic substrate. The optical module according to claim 4, wherein a precision processing hole constituting at least a part of the guide pin hole is formed in the optical module.   6. The module main body is provided with at least one of a semiconductor integrated circuit element for driving optical elements and a semiconductor integrated circuit element for amplifying optical signals. The optical module according to item.   The optical module according to claim 6, wherein the optical element is disposed on the side end surface side of the ceramic substrate, and the semiconductor integrated circuit element is disposed on the substrate main surface side of the ceramic substrate.   8. The optical module according to claim 2, wherein a metal body is provided on a surface other than the front end surface and the rear end surface in the module main body. 9.   The optical module according to claim 2, wherein the module body is provided with a plurality of electrical connection terminals. A ceramic substrate used in an optical module having a shape and size that can be coupled to a plug of an optical fiber connector using a guide pin,
A substrate main surface and a side end surface perpendicular to the substrate main surface are provided, and a filling recess is formed in the side end surface, and a filling material made of a material having better workability than the substrate material is filled in the filling recess. A ceramic substrate for an optical module, wherein a precision processed hole constituting at least a part of a guide pin hole is formed in the filler. A module main body having a shape and a dimension that can be coupled to a plug of an optical fiber connector by a plug-guide pin-plug coupling method using a guide pin dedicated to the connector and a clamp spring dedicated to the connector;
An optical module, comprising: an optical element provided on the module main body and having an optical axis aligned when the plug and the module main body are coupled by insertion of the guide pin. With respect to the plug of the optical fiber connector, in a state where the exposed end surface of the optical fiber in the plug and the front end surface of the plug are butted together, a module body that can be coupled using a guide pin dedicated to the connector;
An optical module, comprising: an optical element provided on the module main body and having an optical axis aligned when the plug and the module main body are coupled by insertion of the guide pin. A coupling structure of an optical module in which an optical element is provided in a module body and a plug of an optical fiber connector,
By inserting a guide pin into the plug and the optical module in a state where the exposed end surface of the optical fiber in the plug and the front end surface of the optical module are abutted, the plug and the optical module are coupled and an optical axis A combined structure of an optical module and a plug of an optical fiber connector, characterized by being combined.

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