Abstract:
An optical module may include precise guide pins formed in a transparent substrate or an optical transmission line support member. The precise guide pins may be inserted into corresponding precise guide holes within the transparent substrate or the optical transmission line support member to precisely align optical elements. The precise guide holes may be formed within one of the transparent substrate and the optical transmission line support member by positioning protruding portions of a jig within over-sized guide holes and filling a gap between the protruding portions of the jig and the respective over-sized guide holes with a filler material. Once the filler material is cured, the jig may be withdrawn leaving precisely positioned guide holes.

Description:
BACKGROUND OF THE INVENTION 
   1. Field of Invention 
   The present invention relates to apparatus, components and the like, which carry out information communication (signal transmission) between a plurality of apparatus or within an apparatus and the like, by using an optical signal. 
   2. Description of Related Art 
   Acceleration of a signal transfer rate between circuit chips or between circuit boards and the like included in various apparatus has advanced, and thus problems of cross talk between signal lines, noise radiation, impedance mismatching, high power consumption and the like are becoming critical. For this reason, optical communication is beginning to be introduced even for signal transmission inside an apparatus. Furthermore, a method of transmitting an optical signal through an optical fiber (tape fiber) or an optical waveguide, instead of other methods of running electric signal in metal wiring, between circuit chips and between modules and the like inside an apparatus, is being employed. 
   When carrying out optical communication, it is important to precisely align the mutual positioning (optical-axis alignment) at nodes, which exist on a transmission path of the optical signal, for example, between optical fibers, and between an optical fiber and a light-emitting element or a photo detector to avoid increase in optical coupling loss. Thus, in order to accomplish these demands, various techniques have been employed. For example, for a multi-core optical plastic connector which is used when coupling a plurality of optical fibers, in case of employing a structure having an intruding pin provided on one of connectors, while a fitting hole, in which the intruding pin is to be inserted, is provided on the other connector, a technique of enhancing precision of the bore diameter of the fitting hole by forming the fitting hole with metal or ceramic, and thus enhancing the positioning precision between fibers has been disclosed. 
   SUMMARY OF THE INVENTION 
   Generally, for optical position alignment between an optical fiber and a light-emitting element or a light-receiving element, high precision, such as a unit of several micron meters, is required. Such high precision position alignment is still difficult to attain even if employing the technique described above, and thus a technique enabling precise and easy optical position alignment is desired. 
   The present invention provide techniques, which enable optical position alignment in apparatus and components, which are used in optical communication, precisely and easily. 
   In order to accomplish the above, an aspect of the present invention provides a method of manufacturing an optical module, which includes a transparent substrate having an electro-optical element on one surface side and an optical transmission line support member, which is arranged on the other surface side of the transparent substrate and supports one end of an optical transmission line, the method of manufacturing the optical module including forming a guide pin in either the transparent substrate or the optical transmission line support member; forming a guide hole, in which the guide pin is to be inserted, in the other one of the transparent substrate and the optical transmission line support member, in which the guide pin is not formed, such that the diameter of the guide hole is made larger as compared with the diameter of the guide pin; arranging a jig having a protruding portion, which diameter is substantially the same as the diameter of the guide pin, so that the protruding portion is inserted into the guide hole; filling up the gap between the protruding portion and the guide hole with a filler material, which is cured by carrying out a predetermined processing; adjusting a position of the jig within a range in which the protruding portion is movable inside the guide hole; curing the filler material by carrying out the predetermined processing on the filler material, which is filled up in the gap between the protruding portion and the guide pin; and pulling out the protruding portion from the guide hole after having cured the filler material. 
   Thus, after having arranged the jig which has the protruding portion, for example, above the transparent substrate, the position of the jig is fine-adjusted according to the configuration of the electro-optical element, and then the filler material is cured to narrow the inner side of the guide hole after the fine adjustment, thereby enabling to form the guide hole with increasing the precision of the formation position, the size and the like. By inserting the guide pin into the guide hole, the mutual positioning of the transparent substrate and optical transmission line support member can be aligned with high precision. Therefore, enhancement of the optical coupling efficiency can be attained by aligning and arranging precisely and easily the mutual positions of the optical transmission line and the electro-optical element. Moreover, what is required for the size of the guide hole is a size, which is sufficient to adjust a position of the protruding portion provided to the jig. Thus there is another advantage that the formation becomes easy because the required precision for the formation position and the hole diameter decreases. 
   Moreover, the manufacturing method may further include mounting the optical transmission line support member on the transparent substrate such that the guide pin is inserted into the guide hole, in which the filler material is already cured. Accordingly, the optical module with sufficient optical coupling efficiency can be attained. 
   Moreover, an aspect of the present invention provides a method of manufacturing an optical module, which includes a transparent substrate having an electro-optical element on one surface side and an optical transmission line support member, which is arranged on the other surface side of the transparent substrate and supports one end of an optical transmission line, the method of manufacturing the optical module including forming the guide hole in either the transparent substrate or the optical transmission line support member; forming a fitting hole, into which a guide pin is to be fitted, in the other one of the transparent substrate and the optical transmission line support member, in which the guide pin is not formed, such that the diameter of the fitting hole is made larger as compared with the diameter of the guide pin; inserting a part of the guide pin into the fitting hole; filling up a gap between the guide pin and the fitting hole with a filler material, which is cured by carrying out a predetermined processing; adjusting a position of the guide pin within a range in which the guide pin can move inside the fitting hole; and curing the filler material by carrying out the predetermined processing on the filler material, which is filled up in the gap between the guide pin and the fitting hole. 
   After the guide pin are inserted into the fitting hole, the position of the guide pin is fine-adjusted according to the configuration and the like of the electro-optical element, and the filler material is cured after the fine adjustment. Therefore, the position of the guide pin can be determined precisely. Thus, by fitting the guide pin, whose position is determined in such a process, with the guide hole, the mutual positions of the transparent substrate and the optical transmission line support member can be adjusted with high precision. Therefore, enhancement of optical coupling efficiency can be attained by aligning and arranging precisely and easily the mutual positions of the optical transmission line and the electro-optical element. What is required for the size of the fitting hole is a size, which is sufficient to adjust a position of the guide pin. Thus there is another advantage that the formation is easy because the required precision for the formation position and the hole diameter decreases. 
   It is preferable that the above-described guide pin is inserted into the fitting hole such that, at least, a part of the guide pin is inserted into a guide pin holding hole by a jig having the guide pin holding hole, whose diameter is substantially the same as the diameter of the guide pin. This simplifies the manufacturing method. 
   Moreover, the method of manufacturing the optical module may further include mounting the optical transmission line support member on the transparent substrate, such that the guide pin, which is fixed in the fitting hole by having cured the filler material, is inserted into the guide hole. Accordingly, an optical module with sufficient optical coupling efficiency can be attained. 
   Moreover, an aspect of the present invention provides a method of manufacturing an optical module, which includes a transparent substrate having an electro-optical element on one surface side and an optical transmission line support member, which is arranged on the other surface side of the transparent substrate and supports one end of an optical transmission line, and each of the electro-optical element and the optical transmission line is arranged on each surface of the transparent substrate or on one surface of the transparent substrate, and coupled optically to each other with the optical coupling member and the like, which takes the role of optical coupling of the electro-optical element and the optical transmission line, the method of manufacturing the optical module including forming a guide pin in either the transparent substrate or the optical transmission line support member; forming a guide hole, in which the guide pin is to be inserted, on the other of the transparent substrate and the optical transmission line support member, in which the guide pin is not formed, such that the diameter of the guide hole is made larger to produce a gap therebetween when the guide pin is inserted into the guide hole; mounting the optical transmission line support member on the transparent substrate such that the guide pin is being inserted into the guide hole; filling up the gap between the guide pin and the guide hole with a filler material, which is cured by carrying out a predetermined processing; adjusting a position of the optical transmission line support member within a range in which the guide pin can move inside the guide hole; and curing the filler material by carrying out the predetermined processing on the filler material, which is filled up in the gap between the guide pin and the guide hole. 
   This configuration enables easy fine-adjustment of the mutual positions of the optical transmission line support member and the transparent substrate after having mounted the optical transmission line support member on the transparent substrate. Thereby the position after the fine adjustment can be determined by curing the filler material after the fine adjustment. Therefore, enhancement of optical coupling efficiency can be attained by aligning and arranging precisely and easily the mutual positions of an optical transmission line and an electro-optical element. Moreover, what is required for the size of the guide hole is a size, which is sufficient to adjust a position of the guide pin, and thus there is another advantage that formation is easy because the required precision for the formation position and the hole diameter decreases. 
   Moreover, an aspect of the present invention provides a method of manufacturing an optical module, which includes: a transparent substrate having an electro-optical element on one surface side; an optical transmission line support member, which is arranged on the other surface side of the transparent substrate and supports one end of an optical transmission line; and an optical coupling member, which is arranged on the other side surface of the transparent substrate and has a role of optical coupling of the electro-optical element with the optical transmission line, the method of manufacturing an optical module including forming a guide pin in either the optical transmission line support member or the optical coupling member; forming a guide hole, in which the guide pin is to be inserted, in the other one of the optical transmission line support member and the optical coupling member, in which the guide pin is not formed, such that the diameter of the guide hole is made larger to produce a gap therebetween when the guide pin is inserted into the guide hole; mounting the optical transmission line support member on the transparent substrate such that the guide pin is inserted into the guide hole; filling up the gap between the guide pin and the guide hole with a filler material, which is cured by carrying out a predetermined processing; adjusting a position of the optical transmission line support member within a range in which the guide pin can move inside the guide hole; and curing the filler material by carrying out the predetermined processing to the filler material, which is filled up in the gap between the guide pin and the guide hole. 
   This configuration enables easy fine-adjustment of the mutual positions of the optical transmission line support member and the optical coupling member after having mounted the optical transmission line support member on the transparent substrate. Thereby the position after fine adjustment can be determined by curing the filler material after the fine adjustment. Therefore, optical coupling efficiency can be enhanced by aligning precisely and easily the mutual positions of the optical transmission line and the electro-optical element. Moreover, what is required for the size of the guide pin is a size, which is sufficient to adjust a position of the guide pin, and thus there is another advantage that the formation is easy because the required precision for the formation position and the hole diameter decreases. 
   Moreover, the method of manufacturing an optical module may further include pulling out the guide pin from the guide hole after having cured the filler material. Accordingly, the guide hole, in which both the position precision and the hole diameter are formed with sufficient precision, can be obtained. This is preferable for a case that the one member, in which the guide pin is provided, and the other member, in which the hole is provided, are constituted detachably. 
   Moreover, the filler material may include either a thermosetting adhesive or an optically-cured adhesive. This enables carrying out the above predetermined processing by applying heat or light, and thus the filler material can be cured easily even under a case of the guide pin being inserted into the guide hole or the fitting hole. 
   Moreover, an aspect of the present invention provides the optical module manufactured using the above-described manufacturing method. Specifically, the optical module of an aspect of the invention has: a transparent substrate which has optical permeability to the wavelength of the light used; an electro-optical element, which is arranged on one surface side of the transparent substrate and radiates signal light toward the other surface side of the transparent substrate according to provided electrical signal, or which generates an electrical signal according to the luminous intensity of signal light provided from the other surface side of the transparent substrate; an optical transmission line support member, which is arranged on the other surface side of the transparent substrate and supports one end of an optical transmission line; and an optical coupling member, which is arranged on the other surface side of the transparent substrate and has a role of optical coupling between the electro-optical element and the optical transmission line. Either the transparent substrate or the optical transmission line support member has a guide pin therein, and the other one has a guide hole, in which the guide pin is to be inserted, and the diameter of the guide hole is made larger as compared with the diameter of the guide pin so that a gap is produced between the guide pin and the guide hole, and the gap between the guide pin and the guide hole is filled up with a predetermined filler material. 
   This configuration enables enhancement in precision of the mutual positions of the electro-optical element, the optical transmission line support member and the optical coupling member. In particular, what is required for the size of the guide hole is a size, which is sufficient to adjust a position of the protruding portion provided to the jig or the guide pin, and thus there is another advantage that the formation becomes easy because the required precision for the formation position and the hole diameter decreases. 
   The above-described optical transmission line support member supports the optical transmission line such that the extension direction of the optical transmission line becomes substantially parallel to the other surface side of the transparent substrate, and the optical coupling member has a reflective portion, which changes the course of signal light radiated from the electro-optical element by substantially 90 degrees to be guided to the optical transmission line, or which changes the course of signal light radiated from the optical transmission line by substantially 90 degrees to be guided to the electro-optical elemen. It is preferable that the guide pin is arranged to become substantially orthogonal to the other surface side of the transparent substrate. Accordingly, miniaturization of the optical module can be accomplished. Moreover, by arranging the guide pin substantially orthogonally, insertion into the guide hole and subsequent position alignment become easier. 
   Moreover, an optical module of an aspect of the present invention has: a transparent substrate, which has an optical permeability to the wavelength of the light used; an electro-optical element, which is arranged on one surface side of the transparent substrate and radiates signal light toward the other surface side of the transparent substrate according to provided electrical signal, or which generates electrical signal according to the luminous intensity of signal light provided from the other surface side of the transparent substrate; an optical transmission line support member, which is arranged on the other surface side of the transparent substrate and supports one end of an optical transmission line; and an optical coupling member, which is arranged on the other surface side of the transparent substrate and has a role of optical coupling between the electro-optical element and the optical transmission line. Either the optical transmission line support member or the optical coupling member has a guide pin therein and the other one has a guide hole, in which the guide pin is to be inserted, and the diameter of the guide hole is made larger as compared with the diameter of the guide pin so that a gap is produced between the guide pin and the guide hole, and the gap between the guide pin and the guide hole is filled up with a predetermined filler material. 
   This configuration enables enhancement in precision of the mutual positions of the electro-optical element, the optical transmission line support member and the optical coupling member. In particular, what is required for the size of the guide hole is a size, which is sufficient to adjust a position of the guide pin, and thus there is another advantage that the formation becomes easy because the required precision for the formation position and the hole diameter decreases. 
   The above-described optical transmission line support member supports the optical transmission line such that the extension direction of the optical transmission line becomes substantially parallel to the other surface side of the transparent substrate, and the optical coupling member has a reflective portion, which changes the course of signal light radiated from the electro-optical element by substantially 90 degrees to be guided to the optical transmission line, or which changes the course of signal light radiated from the optical transmission line by substantially 90 degrees to be guided to the electro-optical element, and the guide pin is arranged to become substantially parallel to the extension direction of the optical transmission line. Accordingly, miniaturization of the optical module can be accomplished. 
   Moreover, the above-described optical coupling member may have a lens, which converges signal light radiated from the electro-optical element to be guided to the reflective portion, or which converges signal light radiated from the optical transmission line and then reflected by the reflective portion to be guided to the electro-optical element. This further increases optical coupling efficiency. 
   Moreover, the optical coupling member may have a first lens, which turns signal light radiated from the electro-optical element into a parallel light to be guided to the reflective portion, or which converges signal light radiated from the optical transmission line and then reflected by the reflective portion to be guided to the electro-optical element, and a second lens, which converges signal light radiated from the electro-optical element and then reflected by the reflective portion to be guided to the optical transmission line, or which turns signal light radiated from the optical transmission line into a parallel light to be guided to the reflective portion. This further increases optical coupling efficiency. 
   Moreover, an optical coupling member may further have a third lens, which turns signal light radiated from the electro-optical element into a parallel light to be guided to the reflective portion, or which converges signal light radiated from the optical transmission line and then reflected by the reflective portion to be guided to the electro-optical element, and that the optical transmission line support member further has a fourth lens, which converges signal light radiated from the electro-optical element and then reflected by the reflective portion to be guided to the optical transmission line, or which turns signal light radiated from the optical transmission line into a parallel light to be guided to the reflective portion. This further increases optical coupling efficiency. 
   Moreover, the above-described reflective portion may have a metal film or a dielectric multilayer film. This increases reflective efficiency. 
   Moreover, an aspect of the present invention is also a hybrid integrated circuit having the above-described optical module, and also a hybrid circuit board. In the specification, the “hybrid integrated circuit” refers to an integrated circuit having a portion, which has a role of processing an electrical signal, and a portion, which has a role of processing an optical signal. Such a hybrid integrated circuit is used, for example, in information communication (data communication) between chips or between circuit boards in various kinds of electronic apparatuses. Moreover, in the specification, the “hybrid circuit board” refers to a circuit board having both circuit wiring, which has a role of transmission of electrical signal, and an optical transmission line, which has a role of transmission of optical signal, and includes the above-described optical module or the hybrid integrated circuit including the optical module. 
   Moreover, an aspect of the present invention is also an electronic apparatus having the above-described optical module. In more detail, the electronic apparatus of an aspect of the invention also includes a case that includes the above-described hybrid integrated circuit or the circuit board, which includes the optical module, as well as the case that includes the above-described optical module itself. In the specification, the “electronic apparatus” refers to the general apparatus, which realizes a certain function using an electronic circuit and the like. Therefore, there is no specific limitation to its configuration. But various apparatus, for example, such as a personal computer, a PDA (personal digital assistant), an electronic notebook and the like are included. The optical modules, the hybrid integrated circuits, or the circuit boards according to an aspect of the present invention can be used in information communication inside the apparatus of these electronic apparatus and information communication to and from the external apparatuses and the like. 
   Moreover, an aspect of the present invention provides a method of manufacturing an opto-electricity mixed device, which includes a circuit board having a conductive film having a role of transmitting an electrical signal and an optical transmission line having a roll of transmitting a signal light, and a hybrid integrated circuit chip, which is coupled to the circuit board and has a role of conversion between the electrical signal and the signal light, the method of manufacturing the opto-electricity mixed device including forming a guide pin in either the hybrid integrated circuit chip or the circuit board; forming a guide hole in the other one of the hybrid integrated circuit chip or the circuit board, in which the guide pin is to be inserted, such that the diameter of the guide hole is made larger as compared with the diameter of the guide pin; arranging a jig having a protruding portion, whose diameter is substantially the same as the diameter of the guide pin, on top of the circuit board so that the protruding portion is being inserted into the guide hole; filling up the gap between the protruding portion and the guide hole with a filler material, which is cured by carrying out a predetermined processing; adjusting a position of the jig within a range in which the protruding portion can move inside the guide hole; curing the filler material by carrying out the predetermined processing on the filler material, which is filled up in the gap between the protruding portion and the guide pin; and pulling out the protruding portion from the guide hole after having cured the filler material. 
   Moreover, an aspect of the present invention provides a method of manufacturing an opto-electricity mixed device, which includes a circuit board having a conductive film having a role of transmitting electrical signal and an optical transmission line having a roll of transmitting a signal light, and a hybrid integrated circuit chip, which is coupled to the circuit board and has a role of conversion between the electrical signal and the signal light, the method of manufacturing the opto-electricity mixed device including forming a guide pin in either the hybrid integrated circuit chip or the circuit board; forming a guide hole in the other one of the hybrid integrated circuit chip and the circuit board, in which the guide pin is to be inserted, and whose diameter is made larger so that a gap is produced between the guide pin and the guide hole when the guide pin is inserted into the guide hole; mounting the hybrid circuit board on top of the circuit board such that the guide pin is inserted into the guide hole; filling up the gap between the guide pin and the guide hole with a filler material, which is cured by carrying out a predetermined processing; adjusting a position of the hybrid integrated circuit chip within a range in which the guide pin can move inside the guide hole; and curing the filler material by carrying out the predetermined processing to the filler material, which is filled up in the gap between the guide pin and the guide hole. 
   This configuration enables precise and easy alignment of the mutual positions of the optical transmission line and the hybrid integrated circuit chip, which the circuit board has, and thus the enhancement of the optical coupling efficiency can be attained. Moreover, what is required for the size of the guide hole is a size, which is sufficient to adjust a position of the protruding portion provided to the jig or the guide pin, and thus there is another advantage that the formation becomes easy because the required precision for the formation position and the hole diameter decreases. 
   The above-described hybrid integrated circuit chip includes a transparent substrate having optical permeability to the wavelength of the light used, and an electro-optical element, which is arranged on one surface side of the transparent substrate and radiates signal light toward the other surface side of the transparent substrate according to provided electrical signal, or which generates an electrical signal according to the luminous intensity of signal light provided from the other surface side of the transparent substrate. It is preferable that either the guide pin or the guide hole is formed on the transparent substrate. 
   Moreover, an aspect of the present invention is also an opto-electricity mixed device manufactured using the above-described manufacturing method. Specifically, the opto-electricity mixed device of an aspect of the invention includes a circuit board having a conductive film having a role of transmitting electrical signal and an optical transmission line having a roll of transmitting signal light, and a hybrid integrated circuit chip, which is coupled to the circuit board and has a role of conversion between the electrical signal and signal light, either the circuit board or the hybrid integrated circuit chip having a guide pin, and the other one having a guide hole, in which the guide pin is to be inserted, whose diameter is made larger as compared with the diameter of the guide pin so that a gap is produced between the guide pin and the guide hole, and, the gap between the guide pin and the guide hole is filled up with a predetermined filler material. 
   This configuration enables precise and easy alignment of the mutual positions of the optical transmission line and the hybrid integrated circuit chip, which the circuit board has, and thus enhancement of the optical coupling efficiency can be attained. Especially, what is required for the size of the guide hole is a size, which is sufficient to adjust a position of the protruding portion provided to the jig or the guide pin, and thus there is another advantage that the formation becomes easy because the required precision for the formation position and the hole diameter decreases. 
   The above-described hybrid integrated circuit chip includes a transparent substrate, which has optical permeability to the wavelength of the light used, an electro-optical element, which is arranged on one surface side of the transparent substrate and radiates signal light toward the other surface side of the transparent substrate according to the provided electrical signal, or which generates electrical signal according to the luminous intensity of signal light provided from the other surface side of the transparent substrate, and it is preferable that the guide pin or the guide hole is formed on the transparent substrate. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIGS. 1(A) and 1(B)  are schematics explaining a configuration of an optical module according to one exemplary embodiment. 
       FIGS. 2(A)–2(D)  are schematics explaining a method of mounting a fiber supporting member. 
       FIGS. 3(A) and 3(B)  are schematics explaining a method of mounting a fiber supporting member. 
       FIGS. 4(A) and 4(B)  are schematics explaining another exemplary embodiment of a configuration of an optical module. 
       FIGS. 5(A) and 5(B)  are schematics explaining another exemplary embodiment of a configuration of an optical module. 
       FIG. 6  is a schematic explaining an exemplary embodiment of configuration of a hybrid integrated circuit and a hybrid integrated board including the hybrid integrated circuit. 
       FIG. 7  is a view explaining another exemplary embodiment of a configuration of a hybrid integrated circuit and a hybrid circuit board including the hybrid integrated circuit. 
       FIG. 8  is a view explaining a configuration of an opto-electricity mixed device. 
       FIGS. 9(A)–9(D)  are schematics explaining a manufacturing method in a case of forming a guide pin for one of a transparent substrate and a fiber supporting member with precise positioning. 
       FIGS. 10(A)–10(C)  are schematics explaining a manufacturing method in a case of forming a guide pin to one of the transparent substrate and a fiber supporting member with positioning precisely. 
   

   DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS 
   Hereinafter, the exemplary embodiments of the present invention will be described referring to the accompanying figures. 
   First Exemplary Embodiment 
     FIG. 1  is a view explaining a configuration of an optical module (opto-electric transmission line conversion connector) of the exemplary embodiment.  FIG. 1(A)  shows a plan view of the optical module of the exemplary embodiment.  FIG. 1(B)  shows a sectional view taken along the A–A′ plane of  FIG. 1(A) . In addition, in  FIG. 1(B) , in order to describe a structure of a guide pin  20  (described hereinafter in detail) and its vicinity, such a region is shown by replacing the sectional view taken along the A–A′ plane. 
   The optical module  1  shown in  FIG. 1  includes a transparent substrate  10 , an electro-optical element  12 , an electronic circuit  14 , a wiring film  16 , a fiber support member  18 , a guide pin  20 , and an optical coupling member  22 . 
   The transparent substrate  10  has optical permeability to the wavelength of the light used, and supports each element, which constitutes the optical nodule  1 . For example, in a case that the wavelength of light radiated from the electro-optical element  12  or light received by the electro-optical element  12  is that of visible light or near the wavelength thereof (for example, 850 nm), it is preferable to constitute the transparent substrate  10  with material, such as glass and plastic. Moreover, in a case that the wavelength of radiated light is relatively long (for example, 1300 nm to 1500 nm), the transparent substrate  10  can be constituted with material, such as silicon and germanium. 
   Moreover, the transparent substrate  10  has guide holes  24 , in which the guide pin  20  which is used to determine the position of the fiber support member  18  is to be inserted. The diameter of the guide hole  24  is formed a little larger as compared with the diameter of the guide pin  20 , such that a certain amount of gap is provided between the guide pin  20  and the hole  24  when the guide pin  20  is inserted. Then, between the guide pin  20  and the guide hole  24 , an adhesive  26  as a filler material, which fills the gap therebetween, is filled up. The adhesive  26  is used as an adjustment member to adjust the mounting position of the fiber support member  18 , and will be described below. 
   The electro-optical element  12  radiates an optical signal according to the driving signal provided from the electronic circuit  14 , or generates an electrical signal according to the luminous intensity of the received signal light, and is arranged at a predetermined position on one surface side of the transparent substrate  10  such that a light-emitting surface or a light-receiving surface is directed toward the transparent substrate  10  side. The light-emitting surface or the light-receiving surface of the electro-optical element  12  is arranged inside an opening provided on the wiring film  16  on the transparent substrate  10 , so that signal light is radiated or incident through the opening and the transparent substrate  10 . For example, when the optical module  1  shown in  FIG. 1 , is used as the information transmitting side, a light-emitting element, such as a VCSEL (surface emission laser), is used as the electro-optical element  12 . When the optical module  1  is used as the information receiving side, the light-receiving element, such as photo diode, is used as the electro-optical element  12 . Although the electro-optical element array is constituted with four electro-optical elements  12 , the number of the electro-optical element  12  is not be limited to such a case. 
   The electronic circuit  14  includes a driver and the like to drive the electro-optical element  12 , and is arranged at a predetermined position on the transparent substrate  10 . The electronic circuit  14  is coupled to the electro-optical element  12  through the wiring film  16  constituted on the transparent substrate  10 , and further coupled to other circuit elements, circuit chips, external apparatuses and the like (not shown), as required. 
   The wiring film  16  is formed on the top surface of the transparent substrate  10  using conductor films, such as copper and the like, and is patterned into a predetermined shape. The wiring film  16  performs mutual electric coupling of the electro-optical element  12 , the electronic circuit  14 , other circuit elements and the like, as described above. 
   The fiber support member (optical transmission line support member)  18  supports a tape fiber  50  as an optical transmission line such that its extension direction becomes substantially parallel to the top surface of the transparent substrate  10 , and is arranged detachably on the top surface of the transparent substrate  10 . Although the exemplary embodiment shows the tape fiber  50  having four cores, it is not limited to such a case. The tape fiber may have any desired number of cores (including one core). The fiber support member  18  may be made of any suitable material, such as glass and plastic. Moreover, although the tape fiber, constituted in the shape of a film, is shown as an example of the optical transmission line, there is no intention to limit to the optical transmission line in such a case, but an optical transmission line, such as other general optical fibers, can be employed. 
   The guide pin  20  is a bar member and may be made of any suitable material, such as metal and the like, and is supported by the fiber supporting member  18 . The guide pin  20  is used to determine the position of the fiber supporting member  18  by fitting with the guide hole  24  provided in the transparent substrate  10 . 
   The optical coupling member  22  is provided attain optical coupling between the electro-optical element  12  and the tape fiber  50  supported by the fiber supporting member  18 , and has a plurality of lenses  28  and a reflective portion  30 . The lens  28  converges signal light radiated from each electro-optical element  12  to be guided to the reflective portion  30 , or converges signal light radiated from the tape fiber  50  to be guided to the electro-optical element  12 . The reflective portion  30  changes the course of signal light substantially by 90 degrees to be guided to the tape fiber  50 , or changes the course of signal light radiated from the tape fiber  50  substantially by 90 degrees to be guided to the electro-optical element  12 . The optical coupling member  22  may be made of any suitable material, such as glass and plastic. After having determined the position of the fiber supporting member  18 , the optical coupling member  22  and the fiber support member  18  are adhered to be fixed. Moreover, it is preferable that the reflective portion  30  is formed using metal film or dielectric multilayer film. 
   The optical module  1  of the exemplary embodiment has such a configuration. And a method of mounting the fiber supporting member  18  on the transparent substrate  10  will be described. 
     FIG. 2  is a view explaining a method of mounting the fiber supporting member  18 . In this view, the vicinity of the guide hole  24  in the transparent substrate  10  is shown. 
   First, as shown in  FIG. 2(A) , the guide hole  24  is formed in the transparent substrate  10 . At this time, the guide hole  24  is formed such that its diameter becomes larger as compared with the diameter of the guide pin  20 , which is to be inserted afterward. 
   Next, as shown in  FIG. 2(B) , a jig  52  having a protruding portion  50 , with a diameter substantially the same as the diameter of the guide pin  20 , is arranged on top side of the transparent substrate  10  such that the protruding portion  50  is inserted into the guide hole  24 . As for the jig  52 , the diameter and the arranging interval of the protruding portion  50  are controlled and formed with high precision so that the position, in which the guide pin  20  should be inserted, can be precisely determined. The diameter of the protruding portion  50  may be conveniently made slightly larger than the diameter of the guide pin  20  within a range of allowable precision. 
   Next, as shown in  FIG. 2(C) , a gap between the guide hole  24  and the protruding portion  50  of the jig  52  is filled up with the adhesive  26  by using a dispenser and the like. At this time, as for the adhesive  26 , the adhesive, such as an optically-cured adhesive, which is cured by irradiating light, a thermosetting adhesive, which is cured by applying heat, and the like, which is cured by carrying out a certain predetermined processing afterward, are used. For example, according to the exemplary embodiment, an UV-cured adhesive, which is cured by irradiating ultraviolet rays (UV irradiation), is used. 
   Next, as shown in  FIG. 2(D) , the position adjustment of the protruding portion  50  (positioning of the jig  52 ) is conducted. By setting the fiber core in the tape fiber  50 , which is supported by the fiber supporting member  18 , as the position reference, the position adjustment is conducted, for example, by aligning a reference mark (not shown) and the like provided on the jig  52  with the electro-optical element  12  so as to attain high optical coupling efficiency between the electro-optical element  12  and the tape fiber  50 . 
   Next, as shown in  FIG. 3(A) , the adhesive  26  is cured by irradiating ultraviolet rays to the adhesive  26 . Accordingly, while the bore of the guide hole  24  is narrowed, the central position thereof is preferably formed with high precision to determine the position of the fiber supporting member  18  using the guide pin  20 . 
   Next, as shown in  FIG. 3(B) , the protruding portion  50  is pulled out from the guide hole  24  after having cured the adhesive  26 . Then, the above-described optical module  1 , shown in  FIG. 1 , is obtained by mounting the fiber supporting member  18  on the transparent substrate  10  with the guide pin  20  inserted into the guide hole  24 . 
   According to the exemplary embodiment, after having arranged the jig  52 , having the protruding portion  50  on top of the transparent substrate  10 , the position of the jig  52  is fine-adjusted according to the arrangement and the like of the electro-optical element  12 , and after the fine adjustment, the inner side of the guide hole  24  is narrowed by curing the adhesive  26 . This enables forming the guide hole  24  with high precision. By inserting the guide pin  20  into the guide hole  24 , high precision alignment of the mutual positions of the transparent substrate  10  and the optical fiber support member  18  becomes possible. Therefore, enhancement of optical coupling efficiency can be attained by aligning and arranging precisely and easily the mutual positions of the optical transmission line and the electro-optical element  12 . Moreover, what is required for the size of the guide hole  24  is a size, which is sufficient to adjust a position of the protruding portion  50  of the jig  52 . Thus there is another advantage that the formation becomes easy because the required precision for the formation position and the hole diameter decreases. 
   According to the above-described exemplary embodiment, the guide pin  20  is provided in the fiber supporting member  18 , and the guide hole  24  is provided in the transparent substrate  10 . However, the same action and effect can be attained, even if the guide pin  20  is provided in the transparent substrate  10  and the guide hole  24  is provided in the fiber supporting member  18 . 
   According to the above-described exemplary embodiment, the guide hole  24  is formed by using the jig  52  having the protruding portion  50 . However, it is also possible to form the guide hole  24  directly using the guide pin  20  provided to the fiber supporting member  18  without using the jig  52 . Specifically, this can be conducted as follows. 
   First, in the above-described process in  FIG. 2(B) , instead of using the jig  52 , the fiber supporting member  18  is mounted on the transparent substrate  10  so as to insert the guide pin  20  into the guide hole  24 . Next, like the process shown in  FIG. 2(C) , the adhesive  26 , which is cured by carrying out a predetermined processing, is filled into the gap between the guide pin  20  and the guide hole  24 . And then, like the process shown in  FIG. 2  (D), the position adjustment of the fiber supporting member  18  is conducted within a range in which the guide pin  20  can move within the guide hole  24 . Then, like the process shown in  FIG. 3(A) , the adhesive  26  is cured by carrying out the predetermined processing to the adhesive  26 , which is filled up in the gap between the guide pin  20  and the guide hole  24 . 
   After having mounted the optical transmission line support member  18  on the transparent substrate  10 , the mutual positions of the optical transmission line support member  18  and the transparent substrate  10  are fine-adjusted. Then by determining the position after the fine adjustment by curing the adhesive  26 , enhancement of the precision of the mutual positions of the transparent substrate  10 , the fiber supporting member  18 , and the optical coupling member  22  can be attained. Therefore, the optical coupling efficiency can be enhanced by aligning precisely and easily the mutual positions of the optical transmission line and the electro-optical element  12 . Moreover, what is required for the size of the guide hole  24  is a size, which is sufficient to adjust a position of the guide pin  20 , and thus there is another advantage that the formation becomes easy because the required precision for the formation position and the hole diameter decreases. 
   As for the configuration of the optical module, besides the one shown in  FIG. 1 , various exemplary embodiments of the configuration can be conceivable. Hereinafter, other exemplary embodiments of the configuration of the optical module will be described. 
     FIG. 4  is a view explaining another exemplary embodiment of a configuration of the optical module.  FIG. 4(A)  shows a plan view of an optical module  1   a .  FIG. 4(B)  shows a sectional view taken along the B–B′ plane shown in  FIG. 4(A) . In  FIG. 4  (B), in order to describe a structure of a guide pin  20   a  and its vicinity, such a region is shown by replacing the sectional view taken along the B–B′ plane. Because the optical module  1   a  shown in  FIG. 4  has, basically, the same configuration as the above described optical module  1  shown in  FIG. 1 , the difference there between will be described mainly hereinafter. 
   As for the optical module  1   a  shown in  FIG. 4 , a fiber supporting member  18   a  and an optical coupling member  22   a  are separately arranged on the transparent substrate  10 . The fiber supporting member  18   a  has a guide pin  20   a , and the position is determined by inserting the guide pin  20   a  into the guide hole  24 . The position of the fiber supporting member  18   a  is determined as in the above-described exemplary embodiment. 
   An optical coupling member  22   a  has a lens  28   a , a reflective portion  30   a , and a lens  32 . The function of the lens  28   a  and the reflective portion  30   a  are the same as that of the lens  28  and the reflective portion  30  described above, respectively. The lens  32  turns signal light radiated from the electro-optical element  12  into a parallel light to be guided to the reflective portion  30   a , or converges signal light radiated from the tape fiber  50  and reflected by the reflective portion  30   a  to be guided to the electro-optical element  12 . The optical coupling member  22   a  is adhered to the transparent substrate  10 . 
   Even in such a configuration, the position is determined after having fine-adjusted the mutual positions of the fiber supporting member  18   a  and the transparent substrate  10 . Therefore, enhancement of the precision of the mutual positions of the transparent substrate  10 , the fiber supporting member  18   a , and the optical coupling member  22   a  can be attained. Accordingly, optical coupling efficiency can be enhanced by aligning precisely and easily the mutual positions of the optical transmission line and the electro-optical element  12 . The same action and effect can be attained, even if the guide pin  20   a  is provided in the transparent substrate  10   a  and the guide hole  24   a  is provided in the fiber supporting member  18   a.    
     FIG. 5  is a view explaining another exemplary embodiment of a configuration of the optical module.  FIG. 5(A)  shows a plan view of an optical module  1   b .  FIG. 5(B)  shows a sectional view taken along the C–C′ plane shown in  FIG. 5(A) . In  FIG. 5  (B), in order to describe the structure of a guide pin  20   b  and its vicinity, such a region is shown by replacing the sectional view taken along the C–C′ plane. Because the optical module  1   b  shown in  FIG. 5  has, basically, the same configuration as the optical module  1  shown in  FIG. 1 , the difference therebetween will be described mainly. 
   As for the optical module  1   b  shown in  FIG. 5 , a fiber supporting member  18   b  and an optical coupling member  22   b  are arranged on the transparent substrate  10 . The position of the fiber supporting member  18   b  is determined by using the guide pin  20   b , which is arranged substantially in parallel with the extension direction of the tape fiber  50 , and by inserting the guide pin  20   b  into a guide hole  34  provided in the optical coupling member  22   b . The position of the fiber supporting member  18   b  is determined as in the above-described exemplary embodiment. 
   The optical coupling member  22   b  has a lens  28   b , a reflective portion  30   b , and a guide hole  34 , and is being adhered to fix to the transparent substrate  10 . The gap between the guide hole  34  and the guide pin  20   b  is filled up with an adhesive  26   b . In the exemplary embodiment, a lens  25 , which converges signal light radiated from the electro-optical element  12  and reflected by the reflective portion  30   b  to be guided to the tape fiber  50 , or turns signal light radiated from the tape fiber  50  into a parallel light to be guided to the reflective portion  30   b , is arranged on one end of the fiber supporting member  18   b.    
   Even in such a configuration, the position is determined after having fine-adjusted the mutual positions of the fiber supporting member  18   b  and the optical coupling member  22   b . Therefore, enhancement of the precision of the mutual positions of the transparent substrate  10 , the fiber supporting member  18   b , and the optical coupling member  22   b  can be attained. Accordingly, optical coupling efficiency can be enhanced by aligning precisely and easily the mutual positions of the optical transmission line and the electro-optical element  12 . The same action and effect can be attained, even if the guide pin  20   b  is provided in the optical coupling member  22   b  and the guide hole  34  is provided in the fiber supporting member  18   b.    
   Second Exemplary Embodiment 
   Next, a hybrid integrated circuit (opto-electricity mixed integrated circuit) constituted using the optical module in the above described exemplary embodiment, and a hybrid circuit board constituted using the hybrid integrated circuit will be described. 
     FIG. 6  is a view explaining an exemplary embodiment of a configuration of a hybrid integrated circuit and a hybrid circuit board including the hybrid integrated circuit. A hybrid circuit board  200  shown in this view includes a hybrid integrated circuit  100  including the optical module  1  (or  1   a ,  1   b ) according to the exemplary embodiments described above, and a wiring board  108 . 
   The hybrid integrated circuit  100  includes the optical module  1  and a signal-processing chip  102 , and has a structure which moulds and integrates both with plastic and the like. The optical module  1  and the signal-processing chip  102  are coupled electrically by wire bonding. The optical module  1  is arranged so as to direct the exit direction of the exiting light from the electro-optical element toward the wiring board  108  side. An optical coupling member  22  provided to the optical module  1  is exposed out of mould resin, and is ready to be able to couple the fiber supporting member  18 . The wiring substrate  108  has a wiring film formed on the top thereof, in which the hybrid integrated circuit  100  is mounted. A socket  106  is arranged on the top surface of the wiring board  108 , and the hybrid integrated circuit  100  is fixed by inserting a pin grid array (PGA)  104  provided to the hybrid integrated circuit  100  into the socket  106 . The hybrid integrated circuit  100  and the hybrid circuit board  200  according to the exemplary embodiment can be applied to various kinds of electronic apparatus, such as a personal computer and the like, and can be used for information communication within apparatus and information communication to and from the external apparatuses and the like. 
     FIG. 7  is a view explaining another exemplary embodiment of a configuration of a hybrid integrated circuit and a hybrid circuit board including the hybrid integrated circuit. A hybrid circuit board  210  shown in this view includes a hybrid integrated circuit  110  including the optical module  1  (or  1   a ,  1   b ) according to the exemplary embodiments described above, and a wiring board  118 . 
   The hybrid integrated circuit  110  includes the optical module  1  and a signal-processing chip  112 , and has a structure which moulds and integrates both with plastic and the like. The optical module  1  is arranged so as to direct the exit direction of the exiting light from the light-emitting element toward the opposite to the wiring board  108  side. The optical coupling member  22  provided to the optical module  1  is exposed out of mould resin, and is ready to be able to couple the fiber supporting member  18 . The wiring substrate  118  has a wiring film formed on the top thereof, in which the hybrid integrated circuit  110  is mounted. The hybrid integrated circuit  110  is coupled to the wiring substrate  118  via a ball grid array (BGA)  114 . The hybrid integrated circuit  110  and the hybrid circuit board  210  according to the exemplary embodiment can be applied to various kinds of electronic apparatus, such as a personal computer and the like, and can be used for information communication within apparatus and information communication to and from the external apparatuses and the like. 
   Third Exemplary Embodiment 
   Next, an opto-electricity mixed device, which has a structure similar to the hybrid circuit board according to the above-described second exemplary embodiment, will be described. 
     FIG. 8  is a view explaining a configuration of an opto-electricity mixed device  300  according to a third exemplary embodiment. An opto-electricity mixed device  300  shown in this view includes a hybrid integrated circuit chip  120  and a circuit board  126 . 
   The hybrid integrated circuit  120  includes an optical module  121  and a signal-processing chip  122 , and has a structure which moulds and integrates the both with plastic and the like. The optical module  121  and the signal-processing chip  122  are coupled electrically by wire bonding. The optical module  121  has a structure which excludes the fiber supporting member  18  and the optical coupling member  22  from the optical module  1  (refer to  FIG. 1 ) in the above-described exemplary embodiment, and is arranged so as to direct the exit direction of the exiting light from the electro-optical element  12  toward the circuit board  126 . The optical module  121  includes a transparent substrate, which has optical permeability to the wavelength of the light used, and the electro-optical element  12  arranged on one side of the transparent substrate. Then, by inserting a guide pin  20   c  into the guide hole provided on the circuit board  126  as well as filling therebetween with an adhesive (filler material), as in the case of the above-described exemplary embodiments, the position between the optical module  121  and the circuit board  126  is adjusted. 
   The circuit board  126  includes a wiring substrate  130  having a conductive film, which has a role of transmission of electrical signal, formed on the top surface thereof, and an optical transmission line (optical waveguide)  132 , which transmits of light information. The optical transmission line  132  has a role of transmitting the optical signal radiated from the electro-optical element, which is included in the hybrid integrated circuit chip  120 , to other apparatus, modules and the like (not shown). The optical transmission line  132  has a reflection mirror formed at an end portion thereof, and the course of the optical signal radiated from the light-emitting element is changed by substantially 90 degrees by the reflection mirror to be incident to the optical transmission line  132 . The course of the optical signal transmitted through the optical transmission line  132  is changed by substantially 90 degrees by the reflection mirror to be incident to the optical module  121 . 
   The hybrid integrated circuit chip  120  and the opto-electricity mixed device  300  according to the exemplary embodiment can be applied to various kinds of electronic apparatuses, such as a personal computer and the like, and can be used for information communication within apparatus and information communication to and from the external apparatuses and the like. 
   The present invention is not limited to the contents of each exemplary embodiment described above, and various modifications of the exemplary embodiments can be made within the scope of the spirit of the present invention. For example, according to the above-described exemplary embodiments, the guide pin is provided to the fiber supporting member and the guide hole is provided to the transparent substrate or the optical coupling member. However, the same action and effect can be attained, even if the guide pin is provided to the transparent substrate or the optical coupling member, and the guide hole is provided to the fiber supporting member. 
   The above-described manufacturing methods shown in  FIGS. 2 and 3  is not limited to the mounting of the electro-optical elements according to the exemplary embodiments, but can be applied to methods, which form a hole precisely in a transparent substrate (for example, a glass substrate and a glass epoxy substrate), which are used for various applications. 
   According to the exemplary embodiments described above, by filling up the filler material into the guide hole, whose diameter is formed larger in advance, the formation position of the guide hole is adjusted while narrowing the diameter of the guide hole. However, the guide pin may be formed to either the transparent substrate or the fiber supporting member (optical transmission line support member) with precise positioning, and then the guide pin may be inserted into the guide hole, which is formed in advance to the other one of the transparent substrate and the fiber supporting member. Hereinafter, a manufacturing method in that case will be described in detail. 
     FIGS. 9 and 10  are views explaining a manufacturing method which forms a guide pin to either the transparent substrate or the fiber supporting member with precise positioning. First, a guide hole is formed in either the transparent substrate  10  or the fiber supporting member  18 . For example, in the exemplary embodiment, the guide hole  408  is formed in the fiber supporting member  18  (refer to  FIG. 10(C) ). In this case, the hole diameter of the guide hole  408  is made substantially same as the diameter of the guide pin  20 , which is to be inserted into the guide hole  408  afterward. 
   Next, as shown in  FIG. 9(A) , a fitting hole, into which the guide pin is to be fitted, is formed in the other one of the transparent substrate and the fiber supporting member, in which the guide pin is not formed, such that the diameter of the fitting hole is made larger as compared with the diameter of the guide pin. In the exemplary embodiment, the fitting hole  400  is formed in the transparent substrate  10 . 
   Next, as shown in  FIG. 9(B) , a part of the guide pin  20  is inserted into the fitting hole  400 . In the exemplary embodiment, the guide pin  20  is inserted into the fitting hole  400  by a jig  404  having a guide pin holding hole  402 , whose diameter is substantially same as the diameter of the guide pin  20  such that, at least, a part the guide pin  20  is being inserted into the guide pin holding hole  402 . 
   Next, as shown in  FIG. 9(C) , an adhesive  406  (filler material) is filled into the gap between the guide pin  20  and the fitting hole  400  by using a dispenser and the like. At this time, as for the adhesive  406 , the adhesive, such as an optically-cured adhesive, which is cured by irradiating light, a thermosetting adhesive, which is cured by applying heat, and the like, which is cured by carrying out a certain predetermined processing afterward, are used. For example, according to the exemplary embodiment, an UV-cured adhesive, which is cured by irradiating ultraviolet rays (UV irradiation), is used. 
   Next, as shown in  FIG. 9(D) , the position of the guide pin  20  is adjusted within a range in which the guide pin  20  can move within the fitting hole  400 . Next, as shown in  FIG. 10(A) , the adhesive  406  is cured by irradiating ultraviolet rays to the adhesive  406 . Accordingly, while the bore of the fitting hole  400  is narrowed, the position of the guide pin  20  is determined at a preferred position with high precision. 
   Next, as shown in  FIG. 10(B) , upon the determination of the position, the jig  404  is taken away from the guide pin  20  that is fixed to the transparent substrate  10 . Then, as shown in  FIG. 10(C) , the fiber supporting member  18  is mounted on the transparent substrate  10  so that the guide pin  20  is being inserted into the guide hole  408 . Accordingly, an optical module having a configuration similar to that of the above-described optical module shown in  FIG. 1  is attained. 
   After the guide pin is inserted into the fitting hole, the position of the guide pin is fine-adjusted according to the configuration and the like of the electro-optical element, and the filler material is cured after the fine adjustment. Therefore, the position of the guide pin can be determined precisely. Thus, by fitting the guide pin, whose position is determined in such a process, with the guide hole, the mutual positions of the transparent substrate and the optical transmission line support member can be adjusted with high precision. Therefore, enhancement of optical coupling efficiency can be attained by aligning and arranging precisely and easily the mutual positions of the optical transmission line and the electro-optical element. What is required for the size of the fitting hole is a size, which is sufficient to adjust a position of the guide pin, and thus there is another advantage that the formation becomes easy because the required precision for the formation position and the hole diameter decreases.