JP3775480B2 - Manufacturing method of optical module - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a method for manufacturing an optical module.
[0002]
BACKGROUND OF THE INVENTION
In recent years, information communication has a tendency to increase in speed and capacity, and optical communication has been developed. In general, in optical communication, an electrical signal is converted into an optical signal, the optical signal is transmitted through an optical fiber, and the received optical signal is converted into an electrical signal. The conversion between the electrical signal and the optical signal is performed by an optical element. An optical module in which an optical element is mounted on a platform is known.
[0003]
In the conventional optical module, it is difficult to align the optical element and the optical fiber. For example, although the position of the optical fiber is aligned using a V-groove formed in the platform, the optical fiber is difficult to handle and it is difficult to perform highly accurate alignment.
[0004]
The present invention is to solve this problem, and an object of the present invention is to provide an optical module that is excellent in handling of optical fibers and has high positional accuracy, a manufacturing method thereof, and an optical transmission device.
[0005]
[Means for Solving the Problems]
  (1) The optical module manufacturing method according to the present invention includes an optical element having an optical portion on one surface.In a recess provided on the platform and having a depth equal to or greater than the thickness of the optical element.A first step mounted on
  Guide portion provided around the end face of the optical waveguideTheGuided portion provided on the platformBy attaching to the optical waveguide and the optical partAlignmentI doA second step;
  including.
[0006]
According to the present invention, the optical waveguide is aligned with the optical element by using the guide portion provided around the end face of the optical waveguide. According to this, since the optical waveguide can be aligned by attaching the guide portion to the guided portion, the optical waveguide is excellent in handling. Therefore, the optical waveguide can be aligned with the optical element with high positional accuracy.
[0007]
Further, if the concave portion is formed at a predetermined position and shape, it is not necessary to align the optical element with the platform, so that the optical module can be easily manufactured.
[0008]
  (2) In this method of manufacturing an optical module,
  The guide portion is a pin protruding in the axial direction of the optical waveguide from the end surface of the optical waveguide,
  The guided portion is a hole formed avoiding the concave portion,
  In the second step,Insert the pin through the holeLetMay be.
[0009]
According to this, the optical waveguide is aligned by inserting the pin through the hole of the platform. Since the pin protrudes in the axial direction of the optical waveguide, the position on the plane perpendicular to the axial direction of the optical waveguide can be determined by inserting the pin through the hole.
[0010]
  (3) In this method of manufacturing an optical module,
  Optical waveguideofAround the edgeIsA fixing portion for fixing the pin is provided;
The fixed portion has a surface that is flush with an end surface of the optical waveguide,
In the second step, a surface that is flush with an end surface of the optical waveguide in the fixed portion is disposed so as to be in contact with an outer surface of the recess in the platform.May be.
[0011]
Accordingly, the pin can be provided around the end face of the optical waveguide.
[0012]
  (4) In this method of manufacturing an optical module,
The depth of the recess is approximately the same as the thickness of the optical element,
A conductive film is formed on a surface that is flush with an end surface of the optical waveguide in the fixed portion,
An electrode is formed on the optical element,
A wiring layer is formed on the platform,
In the second step, the conductive film may be electrically connected to the wiring layer of the platform and the electrode of the optical element.
[0014]
  (5) In this method of manufacturing an optical module,
The guided portion is a depression,
The recess is provided inside the recess;
In the second step, the guide portion may be fitted into the recess.
[0015]
(6) In this method of manufacturing an optical module,
The guide portion has a surface that is flush with an end surface of the optical waveguide,
In the second step, a surface that is flush with an end surface of the optical waveguide in the guide portion may be disposed so as to be in contact with a surface inside the recess and outside the recess in the platform.
[0016]
  (7In this optical module manufacturing method,
The depth of the recess is approximately the same as the thickness of the optical element,
A conductive film is formed on a surface that is flush with an end surface of the optical waveguide in the guide portion,
An electrode is formed on the optical element,
A wiring layer is formed on the platform,
In the second step, the conductive film may be electrically connected to the wiring layer of the platform and the electrode of the optical element.
[0017]
(8) In this method of manufacturing an optical module,
The depth of the recess is greater than the thickness of the optical element,
In the second step, the end face of the optical waveguide and the optical portion may be disposed in a non-contact manner.
[0018]
  (9In this optical module manufacturing method,
  Optical elementInIsElectrodes are formed,
  In the platform, a wiring layer is formed in a region including the recess,
  It may further include electrically connecting the wiring layer formed inside the recess and the electrode with a wire.
[0019]
According to this, since the optical element and the wiring layer are electrically connected by the wire, the cost is low.
[0020]
  (10In this optical module manufacturing method,
  Inside the recess of the platform, of the optical partUpward,It may further include providing a lens unit.
[0021]
Thereby, the light intensity distributions of the optical portion and the optical waveguide can be matched.
[0022]
  (11In this optical module manufacturing method,
  The recess may have a plurality of bottom surfaces forming a plurality of steps, and may be formed so as to widen from the bottom surface in the opening direction.
[0033]
  (12The optical module according to the present invention is manufactured from the above optical module manufacturing method.
[0034]
  (13) The optical module according to the present invention has an optical part on one surface.DoAn optical element;
A depth greater than or equal to the thickness of the optical elementRecessA platform on which the optical element is mounted in the recess;
  An optical waveguide disposed with an end face facing the optical portion;
  Of the optical waveguideEnd faceA positioning guide provided around the
  The guide portion provided on the platformWas attachedA guided portion;
  including.
[0035]
According to the present invention, the guide portion provided around the end face of the optical waveguide is used to align the optical waveguide with the optical element. According to this, since the guide portion is attached to the guided portion and the optical waveguide is aligned, the handling of the optical waveguide is excellent. Therefore, it is possible to provide an optical module in which the optical waveguide is aligned with the optical element with high positional accuracy.
[0036]
Further, if the recess is formed in a predetermined position and shape, it is not necessary to align the optical element with the platform, so that the optical module can be easily manufactured and a low-cost optical module can be provided.
[0037]
  (14In this optical module,
  The guide portion is a pin protruding in the axial direction of the optical waveguide from the end surface of the optical waveguide,
  The guided portion is a hole formed avoiding the concave portion,
  The pin is,The hole may be inserted.
[0038]
According to this, the optical waveguide is aligned by inserting the pin through the hole of the platform. Since the pin protrudes in the axial direction of the optical waveguide, the position on the plane perpendicular to the axial direction of the optical waveguide is determined.
[0039]
  (15In this optical module,
  Optical waveguideofAround the edgeIsA fixing portion for fixing the pin is provided;
The fixed portion has a surface that is flush with an end surface of the optical waveguide,
The surface that is flush with the end surface of the optical waveguide in the fixed portion may be in contact with the outer surface of the recess in the platform.
[0040]
Accordingly, the pin can be provided around the end face of the optical waveguide.
[0041]
  (16In this optical module,
The depth of the recess is approximately the same as the thickness of the optical element,
A conductive film is formed on a surface that is flush with an end surface of the optical waveguide in the fixed portion,
An electrode is formed on the optical element,
A wiring layer is formed on the platform,
The wiring layer of the platform and the electrode of the optical element may be electrically connected by the conductive film.
[0042]
(17) In this optical module,
The guided portion is a depression,
The recess is provided inside the recess;
The guide portion may be fitted in the recess.
[0043]
  (18In this optical module,
The guide portion has a surface that is flush with an end surface of the optical waveguide,
A surface that is flush with an end surface of the optical waveguide in the guide portion may be disposed so as to be in contact with a surface inside the recess and outside the recess in the platform.
[0045]
  (19In this optical module,
The depth of the recess is approximately the same as the thickness of the optical element,
  The guide partIn the surface that is flush with the end surface of the optical waveguide inA conductive film is formed,
An electrode is formed on the optical element,
  A wiring layer is formed on the platform,
By the conductive film, the platformThe wiring layer and the optical elementOf the electrodeAnd may be electrically connected.
[0046]
(20) In this optical module,
The depth of the recess is greater than the thickness of the optical element,
The end face of the optical waveguide and the optical part may be arranged in a non-contact manner.
[0047]
  (21In this optical module,
  Optical elementInIsElectrodes are formed,
  In the platform, a wiring layer is formed in a region including the recess,
  The wiring layer formed inside the recess and the electrode may be electrically connected by a wire.
[0048]
According to this, since the optical element and the wiring layer are electrically connected by the wire, the cost is low.
[0049]
  (22In this optical module,
  Inside the recess of the platform and of the optical partUpwardYou may further include the provided lens part.
[0050]
Thereby, the light intensity distributions of the optical portion and the optical waveguide can be matched.
[0051]
  (23In this optical module,
  The recess may have a plurality of bottom surfaces forming a plurality of steps, and may be formed so as to widen from the bottom surface in the opening direction.
[0062]
  (24The light transmission device according to the present invention has a light emitting partOn one sideA light emitting device having
A concave portion having a depth equal to or greater than a thickness of the light emitting element, and a first platform on which the light emitting element is mounted in the concave portion;
  Receiving partOn one sideA light receiving element having,
A recess having a depth equal to or greater than the thickness of the light receiving element, and a second platform on which the light receiving element is mounted in the recess;
  An optical waveguide that is disposed with one end face facing the light emitting section and the other end face facing the light receiving section;
  Around both end faces of the optical waveguideEach ofA positioning guide provided on the
  The first and second platformsEach ofA guided portion to which any one of the guide portions is attached;
  including.
[0063]
According to the present invention, the guide portion provided around the end face of the optical waveguide is used to align the optical waveguide with the optical element. According to this, since the guide portion is attached to the guided portion and the optical waveguide is aligned, the handling of the optical waveguide is excellent. Therefore, it is possible to provide an optical transmission device in which the optical waveguide is aligned with the optical element with high positional accuracy.
[0064]
Further, if the recess is formed at a predetermined position and shape, it is not necessary to align the optical element with the platform, so that the optical module can be easily manufactured and a low-cost optical transmission device can be provided.
[0065]
  (25) In this light transmission device,
  A plug connected to the light receiving element;
  A plug connected to the light emitting element;
  May further be included.
[0066]
DETAILED DESCRIPTION OF THE INVENTION
Preferred embodiments of the present invention will be described below with reference to the drawings. However, the present invention is not limited to the following embodiments.
[0067]
(First embodiment)
1 to 3 are diagrams showing an optical module and a manufacturing method thereof according to a first embodiment to which the present invention is applied. As shown in FIG. 3, the optical module includes an optical element 10, a platform 20, and an optical fiber 40. The relative positions of the optical element 10 and the optical fiber 40 are determined by pins 50 (guide portions). The optical fiber 40 is an example of an optical waveguide.
[0068]
The optical element 10 may be a light emitting element or a light receiving element. As an example of the light emitting element, a surface light emitting element, in particular, a surface emitting laser can be applied. A surface emitting element such as a surface emitting laser emits light in a direction perpendicular to the platform. The optical element 10 has an optical portion 12. When the optical element 10 is a light emitting element, the optical part 12 is a light emitting part, and when the optical element 10 is a light receiving element, the optical part 12 is a light receiving part.
[0069]
The optical element 10 is in a state where the relative position with the optical fiber 40 is fixed. Specifically, the relative position of the optical portion 12 of the optical element 10 with respect to the end face 46 of the optical fiber 40 is fixed. The end face 46 of the optical fiber 40 is fixed while facing the optical portion 12.
[0070]
The optical element 10 has at least one (generally two or more) electrodes. For example, the first electrode 14 may be provided on the surface on which the optical portion 12 is formed. Further, the second electrode 16 may be provided on a different surface from the surface on which the first electrode 14 is provided. The second electrode 16 may be formed on a surface opposite to the surface on which the optical portion 12 of the optical element 10 is formed.
[0071]
The optical element 10 is mounted on the platform 20. Specifically, the optical element 10 is mounted inside a recess 30 (see FIG. 1) formed in the platform 20. The shape of the platform 20 is not particularly limited, and may be any of a rectangular parallelepiped, a cube, or a sphere, for example, but has at least one recess 30. The material constituting the platform 20 is not particularly limited, and may be any of an insulator, a conductor, and a semiconductor, and may be any metal such as silicon, ceramic, iron, copper, or a resin. When resin is used, the platform 20 may be formed by injection molding.
[0072]
A wiring layer 22 is formed on the platform 20. Since the wiring layer 22 is electrically connected to the optical element 10, it may be a wiring pattern as necessary. When the platform 20 is formed of a conductive material, it is preferable to form the wiring layer 22 via an insulating film. For example, when the platform 20 is made of silicon, a silicon oxide film may be formed on the surface, and the wiring layer 22 may be formed thereon. The wiring layer 22 can be formed by sputtering, etching with respect to the conductive foil, or plating treatment (whether electrolytic or electroless). The wiring layer 22 is formed at least in a region where the optical element 10 is mounted. Specifically, the wiring layer 22 is formed at least in a region inside the recess 30.
[0073]
A hole 24 is formed in the platform 20. A pin 50 is inserted into the hole 24. Since the pin 50 is fixed around the end face 46 of the optical fiber 40, the optical fiber 40 is fixed to the platform 20 by inserting the pin 50 into the hole 24. Thereby, the relative position of the optical fiber 40 with respect to the optical element 10 is fixed. In addition, the pin 50 is a guide part used when aligning the optical fiber 40, and the hole 24 is a guided part to which the guide part is attached.
[0074]
The hole 24 is formed so as to avoid the recess 30 in which the optical element 10 is mounted. The planar outer shape of the hole 24 is not limited, but is preferably substantially the same as the outer shape of the pin 50. By doing so, the position of the optical fiber 40 can be fixed by inserting the pin 50 into the hole 24. A plurality of holes 24 may be formed in the platform 20. In that case, a plurality of pins 50 are also prepared, and one pin 50 is inserted into one hole 24. Each hole 24 may be arranged at a position that is line-symmetric with respect to a straight line including the center point of the optical fiber 40. Or you may arrange | position in the position which encloses the center point of the optical fiber 40, connects all by the straight line, and draws the polygon more than a triangle. The hole 24 may penetrate the platform 20 or may be a recess that does not penetrate.
[0075]
The optical element 10 is mounted on the inner side of the recess 30 so that the surface opposite to the surface having the optical portion 12 is directed. The optical portion 12 of the optical element 10 faces the opening direction of the recess 30. The recess 30 is formed to be recessed from the surface around the platform 20 and has a space in which the optical element 10 can be mounted inside. Specifically, it is preferable that the bottom surface of the recess 30 (the first bottom surface 32 in FIG. 1) has an outer shape substantially equal to the surface opposite to the surface having the optical portion 12 of the optical element 10. By doing so, if the optical element 10 is fitted into the recess 30, the alignment with respect to the platform 20 can be performed, so that it is not necessary to provide an alignment process again. Therefore, an optical module can be manufactured easily and at low cost. The depth of the recess 30 is preferably deeper than at least the thickness of the optical element 10. For example, the recess 30 may be approximately 50 to 500 μm deeper than the thickness of the optical element 10. This allows the optical fiber 40 to be attached to the platform 20 without bringing the end face 46 of the optical fiber 40 into contact with the optical portion 12.
[0076]
When a plurality of optical elements 10 are mounted on one platform 20, a plurality of recesses 30 are formed on one platform 20. A plurality of optical fibers 40 are also provided corresponding to each optical element 10.
[0077]
The recess 30 may have a plurality of bottom surfaces (first and second bottom surfaces 32 and 34 in FIG. 1). The first and second bottom surfaces 32 and 34 are provided in a plurality of steps so that the recess 30 is wider from the bottom surface (first bottom surface 32) in the opening direction. In the example shown in FIG. 1, a second bottom surface 34 is provided above the first bottom surface 32. Although the level | step difference of the 1st and 2nd bottom surfaces 32 and 34 is not limited, For example, about 1.0 mm or less may be sufficient. The first and second bottom surfaces 32 and 34 are preferably parallel to each other, and are also preferably parallel to the surface of the optical element 10. The surface connecting the first and second bottom surfaces (wall surface of the recess 30) may be, for example, a wall surface perpendicular to the first bottom surface 32, or may be a tapered wall surface. Good. The wiring layer 22 is formed so as to reach the first and second bottom surfaces 32 and 34, and is also formed on the wall surface connecting the first and second bottom surfaces 32 and 34.
[0078]
When the taper is applied, the taper may be a forward taper in which the opening is narrowed in the depth direction, or a reverse taper. When a forward taper is applied, the optical element 10 and passive components can be easily inserted. Moreover, it becomes easy to form the pattern of the wiring layer 22 on the wall surface with the forward taper or on the corner portion where the wall surface and the other surface are connected. That is, the wiring layer 22 can be reliably formed in the recess 30 when using a sputtering process, a photolithography process, or the like. In the case of forward taper, the wall surface of the recess 30 may be an inclined surface of about 5 to 45 degrees from the surface perpendicular to the first bottom surface 32, for example. When a reverse taper is applied, even if a large amount of die attach material for adhering the optical element 10 to the first bottom surface 32 is provided, pooling is possible, so that the die attach material is moved from the side surface to the upper surface of the optical element 10. It is possible to prevent wraparound.
[0079]
The optical element 10 is mounted on the first bottom surface 32. The first bottom surface 32 is the lowermost bottom surface of the recess 30. The second electrode 16 of the optical element 10 is electrically connected to the portion of the wiring layer 22 formed on the first bottom surface 32. The optical element 10 may be bonded to the first bottom surface 32 with the adhesive 18. In this case, if the adhesive 18 is a conductive adhesive, the electrical connection between the optical element 10 and the wiring layer 22 and the mechanical connection between the optical element 10 and the platform 20 can be achieved simultaneously.
[0080]
A hole 36 (see FIG. 1) may be formed in the first bottom surface 32. The hole 36 is formed inside the first bottom surface 32. By doing so, when the optical element 10 is bonded with the adhesive 18, excess adhesive 18 enters the hole 36, so that the positional accuracy of the optical element 10 in the height direction can be increased. That is, it is possible to prevent the optical element 10 from being inclined with respect to the first bottom surface 32 without making the interface of the paste adhesive 18 with the optical element 10 uneven. The hole 36 may be one or more grooves. Alternatively, it can be said that one or more protrusions are formed on the first bottom surface 32.
[0081]
The optical element 10 may be electrically connected to the wiring layer 22 with a wire 26. Specifically, the first electrode 14 of the optical element 10 is electrically connected to the wiring layer 22 by a wire 26. The wire 26 may be bonded to a portion of the wiring layer 22 that is formed inside the recess 30. In that case, the wire 26 may be bonded to a portion of the wiring layer 22 formed on the second bottom surface 34. And the vertex of the loop of the wire 26 is arrange | positioned so that it may become lower than the surface (imaginary surface) in which the opening edge part of the recessed part 30 is located. By doing so, as shown in FIG. 3, even if the optical fiber 40 is attached to the platform 20, the wire 26 is not broken, so that the reliability of electrical connection is high. The second bottom surface 34 may be the same height as the surface having the optical portion 12 of the optical element 10, or may be lower or higher.
[0082]
The optical fiber 40 includes a core 42 and a clad 44 that concentrically surrounds the core 42. Light is reflected at the boundary between the core 42 and the clad 44, and the light is confined in the core 42 and propagates. is there. The optical fiber 40 may be formed of a material such as glass or plastic. Different materials may be used for the core 42 and the clad 44. Note that the periphery of the clad 44 is often protected by a jacket (not shown), particularly in a portion excluding the end portion.
[0083]
A pin 50 is provided around the end face 46 of the optical fiber 40. The pin 50 protrudes in the axial direction of the optical fiber 40 from the end face 46 of the optical fiber 40. The pin 50 may extend in a direction parallel to the axial direction of the optical fiber 40. When the plurality of optical fibers 40 are aligned at the same time, the pins 50 may be disposed on both sides of the group of optical fibers 40, for example, avoiding the end faces 46 of the plurality of optical fibers 40. The material of the pin 50 is not limited. The pin 50 may be referred to as a protrusion that is inserted into the hole 24.
[0084]
As shown in FIG. 3, a fixing portion 52 that fixes the pin 50 to the optical fiber 40 may be provided at the end of the optical fiber 40. The fixing portion 52 may be provided so as to cover the periphery of the end portion while avoiding the end face 46 of the optical fiber 40. As shown in FIG. 3, the fixing portion 52 may have a surface that is flush with the end surface 46 of the optical fiber 40. In that case, the surface that is flush with the end surface 46 of the optical fiber 40 of the fixing portion 52 may be in contact with the outer surface of the recess 30 in the platform 20. That is, the fixed portion 52 may be used for the alignment of the optical fiber 40 in the axial direction. Further, the fixing part 52 has a role as a stopper for making the end face 46 of the optical fiber 40 non-contact with the optical part 12. An adhesive may be interposed between the fixed portion 52 and the platform 20.
[0085]
One fixing portion 52 may be provided in one optical fiber 40, or one fixing portion 52 may be provided in a plurality of optical fibers 40. The fixing part 52 may be formed of ceramic or the like. The fixing portion 52 may be referred to as a ferrule. Further, a member may be provided at the end portion of each optical fiber 40 so as to cover the periphery, and the plurality of optical fibers 40 may be attached to one fixed portion 52 collectively.
[0086]
If necessary, the optical element 10 may be sealed by providing a resin (not shown) in the recess 30. In that case, it is preferable to use a resin having a property of transmitting light at least between the optical portion 12 and the end face 46 of the optical fiber 40. The light transmitting resin is provided in close contact with the optical portion 12 and the end face 46 of the optical fiber 40. Thereby, the loss of light transmission can be reduced and the reliability of the electrical connection portion of the optical element 10 can be increased.
[0087]
In the optical module according to the present embodiment, the pin 50 provided at the end of the optical fiber 40 is used to align the optical fiber 40 with the optical element 10. According to this, since the pin 50 is inserted into the hole 24 and the optical fiber 40 is aligned, the handling of the optical fiber 40 is excellent. Therefore, it is possible to provide an optical module in which the optical fiber 40 is aligned with the optical element 10 with high positional accuracy.
[0088]
Further, if the concave portion 30 is formed in a predetermined position and shape as described above, it is not necessary to align the optical element 10 with the platform 20, so that the optical module can be easily manufactured and the optical module can be manufactured at low cost. Can provide.
[0089]
Furthermore, since the wire 26 is used for the electrical connection between the optical element 10 and the wiring layer 22, the cost can be reduced. Since the optical portion 12 faces the opening direction of the recess 30 and is provided close to the end face 46 of the optical fiber 40, the optical fiber 40 is aligned with the optical portion 12 with high positional accuracy. The Therefore, a low-cost and high-quality optical module can be provided.
[0090]
The optical module according to the present embodiment is configured as described above, and the manufacturing method thereof will be described below. In addition, the structure, operation | movement, and effect which were demonstrated above are applicable as much as possible also in the following manufacturing methods.
[0091]
First, the optical element 10 and the platform 20 described above are prepared. The optical element 10 is mounted on the platform 20. Specifically, the optical element 10 is mounted with the surface opposite to the surface having the optical portion 12 facing the first bottom surface 32 of the recess 30. In that case, if the recess 30 is formed at a predetermined position and shape on the platform 20, it is not necessary to realign the optical element 10 with the platform 20. That is, the first bottom surface 32 of the concave portion 30 is formed with a shape substantially equal to the surface opposite to the surface of the optical element 10 having the optical portion 12. Thus, the optical element 10 can be aligned with the platform 20 simply by dropping the optical element 10 so that the surface opposite to the surface having the optical portion 12 is directed.
[0092]
When the optical element 10 is bonded in the recess 30, the adhesive 18 may be provided on the optical element 10 side as shown in FIG. 1, or may be provided on the platform 20 side, and provided on both of them. Also good. In that case, the adhesive 18 may be a film or a paste at room temperature. In the case where the second electrode 16 is formed on the surface opposite to the surface having the optical portion 12 of the optical element 10, the adhesive 18 preferably has conductivity. Thereby, both the mechanical connection of the optical element 10 and the electrical connection to the wiring layer 22 can be achieved simultaneously. The conductive adhesive 18 may be a silver paste, for example.
[0093]
Then, the optical element 10 is pressurized toward the recess 30. In that case, the optical element 10 may be heated. Then, the optical element 10 is fixed in the recess 30 by developing the adhesive force of the adhesive 18. Since a part of the melted adhesive 18 enters the hole 36 formed in the first bottom surface 32, the optical element 10 can be prevented from being inclined with respect to the first bottom surface 32.
[0094]
As shown in FIG. 2, the first electrode 14 of the optical element 10 and the wiring layer 22 of the platform 20 are electrically connected by a wire 26. The wire 26 may be bonded by a wire bonder used for manufacturing a semiconductor device. The wire 26 is cut after the tip formed in a ball shape by discharge is bonded to one of the first electrode 14 and the wiring layer 22, the intermediate portion is looped and bonded to the other, and then cut. The wire 26 may be bonded to the first electrode 14 of the optical element 10 first, or may be bonded to the wiring layer 22 of the platform 20 first. Bumps 28 may be formed in advance on the side to be bonded later (first electrode 14 or wiring layer 22). The bump 28 may be formed of the same material as the wire 26. Forming the bumps 28 facilitates bonding. This is particularly effective when the heights of the bonding surfaces of the first electrode 14 and the wiring layer 22 do not change much. The wire 26 may be bonded by at least one of heat, pressure, and ultrasonic vibration, and the material may be made of, for example, gold or aluminum.
[0095]
Next, the optical fiber 40 is mounted in alignment with the optical portion 12. The optical fiber 40 is provided with a pin 50 at its end. The pin 50 protrudes in the axial direction of the optical fiber 40 from the end face of the optical fiber 40. In the example illustrated in FIG. 2, the pin 50 is fixed to a fixing portion 52 provided around the end of the optical fiber 40.
[0096]
The alignment of the optical fiber 40 is performed by inserting the pin 50 into the hole 24 of the platform 20. When a plurality of pins 50 are provided at the end of the optical fiber 40, a plurality of holes 24 are provided in the platform 20. The hole 24 is provided so as to avoid the recess 30, and one pin 50 is inserted into one hole 24. Each hole 24 and each pin 50 are provided at positions where the central axes of the core 42 of the optical fiber 40 and the optical portion 12 coincide with each other. The pin 50 may penetrate the platform 20 or may be fastened inside the platform 20. Since the pin 50 protrudes in the axial direction of the optical fiber 40, the optical fiber 40 can be fixed at a position on a plane perpendicular to the axial direction by inserting the pin 50 into the hole 24.
[0097]
The alignment of the optical fiber 40 in the axial direction may be performed by bringing the side of the fixing portion 52 facing the platform 20 into contact with the platform 20. Specifically, the fixing portion 52 is brought into contact with the outer surface of the recess 30. And when the depth of the recessed part 30 is deeper than the height of the optical element 10, it can prevent contacting the optical fiber 40 with the optical part 12. FIG.
[0098]
A resin (not shown) may be provided in the recess 30 before or after the optical fiber 40 is aligned. In that case, the optical element 10 and the wire 26 may be sealed with resin. When the resin is also provided above the optical portion 12, it is preferable to use a resin having a property of transmitting light at least between the optical portion 12 and the end face 46 of the optical fiber 40. The fixing portion 52 may be bonded and fixed to the platform 20 using a resin provided in the concave portion 30. Alternatively, the resin may be provided up to the outer surface of the recess 30.
[0099]
Further, it is preferable to polish the end face 46 before aligning the optical fiber 40. This step is performed in a state where the fixing portion 52 is attached to the optical fiber 40. Specifically, the surface of the fixed portion 52 on the end surface 46 side of the optical fiber 40 is polished so that the end surface 46 of the optical fiber 40 is flush with the surface of the fixed portion 52. According to this, if the surface of the fixing portion 52 is polished, the end surface 46 of the optical fiber 40 is polished, so that the optical fiber 40 is easy to handle. Then, in the subsequent steps, the fixing portion 52 of the optical fiber 40 is used as it is, and alignment may be performed with the pin 50.
[0100]
According to the manufacturing method of the optical module according to the present embodiment, the optical fiber 40 is aligned with the optical element 10 using the pin 50 provided at the end of the optical fiber 40. According to this, since the optical fiber 40 can be aligned by attaching the pin 50 to the hole 24, the optical fiber 40 is excellent in handling. Therefore, the optical fiber 40 can be aligned with the optical element 10 with high positional accuracy.
[0101]
In addition, if the recess 30 is formed in a predetermined position and shape, it is not necessary to align the optical element 10 with the platform 20, so that an optical module can be easily manufactured.
[0102]
(Second Embodiment)
4 to 6 are diagrams showing an optical module and a method for manufacturing the same according to a second embodiment to which the present invention is applied. In the example shown below, the contents described in other embodiments can be applied as much as possible.
[0103]
As shown in FIG. 6, the optical module includes an optical element 10, a platform 120, and an optical fiber 40. The platform 120 includes a wiring layer 122 and includes a recess 30 (see FIG. 4) that is recessed from the surrounding surface. The contents of the wiring layer 122 and the recess 30 are as described in the above embodiment. The relative positions of the optical element 10 and the optical fiber 40 are determined by the guide portion 150.
[0104]
A recess 140 is formed in the platform 120. The depression 140 is a guided portion to which the guide portion 150 is attached. As shown in FIG. 1, the recess 140 has a recess 30 inside thereof. In other words, the depression 140 is formed in communication with the depression 30 above the depression 30, and the outer circumference of the depression 140 is larger than the outer circumference of the depression 30. That is, the hole formed by combining the recess 30 and the recess 140 forms a plurality of steps on the platform 120 from the first bottom surface 32 of the recess 30 to the opening direction of the recess 140. It is preferable that the outer shape in plan view from the opening side of the recess 140 is substantially equal to the outer shape in plan view from the end face side of the optical fiber 40 of the guide portion 150. By doing so, the guide portion 150 having the optical fiber 40 at the center is fitted in the recess 140 without a gap. Therefore, the core 42 and the optical part 12 are accurately aligned. The depth of the recess 140 is not particularly limited as long as the guide portion 150 can be fixed on a plane perpendicular to the axial direction of the optical fiber 40. Note that the wall surface of the recess 140 may be a wall surface perpendicular to the bottom surface outside the recess 30, or may be tapered such that the opening is narrowed in the depth direction, for example.
[0105]
A guide portion 150 is fitted in the recess 140. Here, the guide portion 150 is provided around the end face 46 of the optical fiber 40. Specifically, the guide portion 150 is provided so as to cover the periphery of the end portion, avoiding the end face 46 of the optical fiber 40. One guide portion 150 may be provided for one optical fiber 40 or one guide portion 150 may be provided for a plurality of optical fibers 40. The guide part 150 may be formed of ceramic or the like. The guide unit 150 may be referred to as a ferrule. Further, a member may be provided at the end of each optical fiber 40 so as to cover the periphery, and the guide unit 150 may be attached to the plurality of optical fibers 40 together. The surface of the guide unit 150 facing the optical element 10 is a flat surface and may be flush with the end surface of the optical fiber 40. Further, the surface of the guide unit 150 facing the optical element 10 may be a circle, a rectangle, or another polygon.
[0106]
The surface that is flush with the end face 46 of the optical fiber 40 of the guide portion 150 may be in contact with the surface inside the recess 140 and outside the recess 30. That is, the alignment of the optical fiber 40 in the axial direction may be performed by aligning the guide portion 150 so as to contact the platform 120. Further, the guide portion 150 serves as a stopper for making the end face 46 of the optical fiber 40 non-contact with the optical portion 12. Note that an adhesive (not shown) may be interposed between the guide unit 150 and the platform 120.
[0107]
Next, a method for manufacturing the optical module according to the present embodiment will be described. In addition, the structure, operation | movement, and effect which were demonstrated above are applicable as much as possible also in the following manufacturing methods.
[0108]
As shown in FIG. 4, the optical element 10 and the platform 120 are prepared. The platform 120 is formed with a recess 140 having a recess 30 inside. In other words, the recess 140 communicates with the recess 30 above the recess 30 and has an outer periphery larger than the outer periphery of the recess 30. The optical element 10 is mounted on the first bottom surface 32 of the recess 30.
[0109]
As shown in FIGS. 5 and 6, the optical fiber 40 is attached in alignment with the optical portion 12. Specifically, the guide part 150 is fitted into the recess 140 of the platform 120. If the outer shape of the recess 140 in plan view from the opening side is substantially equal to the outer shape of the guide portion 150 in plan view from the end face side of the optical fiber 40, the guide portion 150 is simply fitted into the recess 140 to The fiber 40 can be aligned with the optical portion 12. The alignment of the optical fiber 40 in the axial direction is performed by bringing a surface that is flush with the end face 46 of the optical fiber 40 of the guide portion 150 into contact with the surface inside the recess 140 and outside the recess 30. Also good.
[0110]
The end face 46 of the optical fiber 40 may be polished with the guide portion 150. Further, if necessary, the recess 30 may be provided with resin. The contents described in the above embodiment can be applied to these.
[0111]
In the manufacturing method of the optical module in the present embodiment, the optical fiber 40 is aligned by fitting the guide portion 150 provided so as to cover the periphery of the end portion of the optical fiber 40 into the recess 140 of the platform 120. . Since only the guide part 150 is fitted in the recess 140, the optical fiber 40 can be easily aligned.
[0112]
(Third embodiment)
7 to 9 are views showing an optical module and a manufacturing method thereof according to a third embodiment to which the present invention is applied. In the example shown below, the contents described in other embodiments can be applied as much as possible.
[0113]
As shown in FIG. 9, the optical module includes an optical element 10, at least one electronic component (for example, a semiconductor chip 110), a platform 220, and an optical fiber 40. The platform 220 includes a wiring layer 222 and includes a plurality of recesses 30 and 60 that are recessed from the surrounding surface. The relative positions of the optical element 10 and the optical fiber 40 are determined by fitting the guide portion 250 into the recess 240.
[0114]
In the present embodiment, a plurality of recesses (for example, recesses 30 and 60 in FIG. 7) are formed in the platform 220. The optical element 10 is mounted in the recess 30, and an electronic component (for example, the semiconductor chip 110) is mounted in the recess 60. Here, the electronic component may be a semiconductor chip, resistor, capacitor, coil, transmitter, filter, temperature sensor, thermistor, varistor, volume, fuse, heat sink, Peltier element, heat pipe, or the like. The electronic component may be a surface mounting type or an insertion mounting type. The electronic component may be mounted face-down with the surface having the electrodes facing the first bottom surface of the recess of the platform 220, or face-up mounting with the opening side of the recess. In addition, the electrical connection between the electronic components or between the electronic component and the wiring layer 222 can be performed using a wire, a conductive adhesive, a bump, or the like.
[0115]
The number of the plurality of recesses (for example, the recesses 30 and 60) may be determined according to the number of optical elements 10 and electronic components mounted on the platform 220. One electronic component may be disposed in one recess, or two or more electronic components may be disposed in one recess. In the latter case, two or more electronic components may be stacked. It is preferable that the first bottom surface (for example, the first bottom surface 62) at the lowermost part of the recess for mounting the electronic component has an outer shape that is substantially equal to the planar outer shape of the electronic component. By doing so, it is possible to align the platform 220 only by dropping the electronic component into the recess.
[0116]
In the example shown in FIG. 9, the optical element 10 is mounted in the recess 30 (see FIG. 7), and the semiconductor chip 110 is mounted in the recess 60 (see FIG. 7). Each of the recesses 30 and 60 may have the form described above, and the first and second bottom surfaces 32, 34, 62, and 64 that form a plurality of steps so that the recesses widen in the opening direction (see FIG. 7). Then, the optical element 10 or the semiconductor chip 110 is mounted on the first bottom surfaces 32 and 62 at the bottom of the concave portions 30 and 60.
[0117]
A recess 240 is formed in the platform 220. The depression 240 is a guided portion to which the guide portion 250 is attached. As shown in FIG. 7, the depression 240 has concave portions 30 and 60 inside. In other words, the recess 240 has an outer periphery with a size including the plurality of recesses 30, 60 and is formed to communicate with the recesses 30, 60. The outer shape in plan view from the opening side of the recess 240 is preferably substantially equal to the outer shape in plan view from the end face side of the optical fiber 40 of the guide portion 250. By doing so, the guide portion 250 having the optical fiber 40 at the center is fitted in the recess 240 without any gap. Therefore, the core 42 and the optical part 12 are accurately aligned. The depth of the recess 240 is not particularly limited as long as the guide portion 250 can be fixed on a plane perpendicular to the axial direction of the optical fiber 40.
[0118]
The guide part 250 is fitted in the recess 240. That is, the guide part 250 is attached to the platform 220 so as to close the plurality of recesses 30 and 60. The surface of the guide portion 250 facing the recess 240 may be a flat surface. The surface may be flush with the end face 46 of the optical fiber 40, or may be in contact with the surface inside the recess 240 and outside each recess 30, 60. That is, the alignment of the optical fiber 40 in the axial direction may be performed by aligning the guide portion 250 so as to contact the platform 220. Further, a member may be provided at the end of each optical fiber 40 so as to cover the periphery, and the guide unit 150 may be attached to the plurality of optical fibers 40 together.
[0119]
As shown in FIG. 9, the first electrode 14 of the optical element 10 and the first electrode 112 of the semiconductor chip 110 are directly electrically connected by a wire 70. Specifically, one tip portion of the wire 70 is bonded to the first electrode 14 of the optical element 10, and the other tip portion is bonded to the first electrode 112 of the semiconductor chip 110. The semiconductor chip 110 is used for driving the optical element 10. By directly joining the optical element 10 and the semiconductor chip 110 with the wire 70, the number of connection points can be reduced, so that poor electrical connection between them can be reduced. In addition, since the wires 70 are directly connected, the wiring length can be shortened and the signal transmission loss can be reduced.
[0120]
As shown in FIG. 9, when the portion between the recess 30 and the recess 60 is formed so high as to reach the surface of the guide portion 250, a part thereof is communicated with each recess 30, 60. It is preferable to form a groove. Since the groove is closed by the guide portion 250, the groove becomes a through hole communicating with the concave portions 30 and 60. According to this, it is possible to electrically connect the optical element 10 and the semiconductor chip 110 disposed in each of the recesses 30 and 60 by passing the wire 70 above the groove (inside the through hole). Accordingly, the optical element 10 and the electronic component can be directly connected by the wire 70 while the guide portion 250 is stably supported by raising the portion between the concave portions 30 and 60.
[0121]
In the optical module manufacturing method according to the present embodiment, as shown in FIG. 7, the optical element 10 is mounted in the recess 30 and the semiconductor chip 110 is mounted in the recess 60. As shown in FIG. 8, the optical element 10 and the semiconductor chip 110 are electrically connected by the wire 70, and the semiconductor chip 110 and the wiring layer 222 are electrically connected by the wire 72. Thereafter, as shown in FIG. 9, the guide portion 250 is attached to the platform 220 so as to close the concave portions 30 and 60.
[0122]
According to this, if the recess 60 for mounting the electronic component is formed in a predetermined position and shape, it is not necessary to align the electronic component with respect to the platform 220, so that the manufacture thereof is easy. Further, since the plurality of recesses 30 and 60 can be closed by the guide portion 250, the optical element 10 and the electronic component are not exposed to the outside. Therefore, it is difficult to receive external influences (for example, moisture intrusion), and a highly reliable optical module can be manufactured.
[0123]
(Fourth embodiment)
10-12 is a figure which shows the optical module which concerns on 4th Embodiment to which this invention is applied, and its manufacturing method. In the example shown below, the contents described in other embodiments can be applied as much as possible.
[0124]
As shown in FIG. 12, the optical module includes an optical element 10, at least one electronic component (for example, a semiconductor chip 110), a platform 320, and an optical fiber 40.
[0125]
The platform 320 has a wiring 322 and a plurality of recesses 130 and 160 that are recessed from the surrounding surface. The optical element 10 is mounted on the first bottom surface 132 of the recess 130, and the semiconductor chip 110 is mounted on the first bottom surface 162 of the recess 160. Holes 136 and 166 into which the adhesives 18 and 116 enter may be formed in the first bottom surfaces 132 and 162, respectively. The relative positions of the optical element 10 and the optical fiber 40 are determined by fitting the guide portion 350 in the recess 340, and the electronic component is electrically connected to the wiring layer 322 by the conductive film 352 formed on the guide portion 350. Connected.
[0126]
  A conductive film 352 is formed on the guide portion 350 on the side facing the recess 340. For example, the conductive film 352 may be formed on the surface of the guide portion 350 that faces the recess 340. The conductive film 352 may be formed using the same material as the wiring layer 322 of the platform 320. The conductive film 352 may be a wiring pattern as necessary. The conductive film 352 electrically connects both the wiring layer 322 and the first electrode 14 of the optical element 10. The conductive film 352 may electrically connect both the wiring layer 322 and the electrodes (first and second electrodes 12 and 14) of the semiconductor chip 110. The conductive film 352 is preferably formed on a flat surface to prevent the disconnection, but may be formed on a plurality of surfaces of the guide portion 350 instead of being flat. When the conductive film 352 is formed on a flat surface, as shown in FIG. 12, the surface of the optical element 10 having the first electrode 14 is a recess.130 open ends are locatedFace andIt is preferable to arrange at substantially the same height. The same applies to the semiconductor chip 110.
[0127]
In addition, the conductive film 352 may be directly connected to both the first electrode 14 of the optical element 10 and the electrode of the semiconductor chip 110 (for example, the first electrode 12). Note that the conductive film 352 may be bonded to the above-described electrode or wiring layer 322 through a conductive adhesive. Or you may join via electroconductive protrusions, such as a bump.
[0128]
In the example shown in FIG. 12, the recess 340 is formed in a plurality of stages in the opening direction. According to this, by forming the guide portion 350 in a shape corresponding to the recess 340, the contact area between the guide portion 350 and the platform 320 can be increased, and both can be mechanically fixed securely. it can. Thus, the conductive film 352 can securely attach the optical element 10 or the electronic component to the wiring layer 322, so that the electrical connection reliability of the optical module can be improved.
[0129]
In the method for manufacturing an optical module according to the present embodiment, as shown in FIG. 10, the optical element 10 is mounted in the recess 30 and the semiconductor chip 110 is mounted in the recess 60. Then, as shown in FIGS. 11 and 12, the guide portion 350 is aligned with the recess 340 and attached to the platform 320 so as to close the concave portions 30 and 60. Electrical connection of the optical element 10 and the semiconductor chip 110 to the wiring layer 320 is achieved by a conductive film 352 formed in the guide portion 350.
[0130]
According to this, by forming the conductive film 352 in the guide portion 350, the optical fiber 40 can be aligned and, for example, the optical element 10 can be electrically connected to the wiring layer 322. Therefore, it is not necessary to provide a process for electrically connecting the optical element 10 to the wiring layer 322, so that the optical module can be manufactured with a small number of processes.
[0131]
(Fifth embodiment)
13 to 15 are views showing an optical module and a manufacturing method thereof according to a fifth embodiment to which the present invention is applied. In the example shown below, the contents described in other embodiments can be applied as much as possible.
[0132]
As shown in FIG. 15, the optical module includes an optical element 10, at least one electronic component (for example, a capacitor 210), a platform 420, and an optical fiber 40. The platform 420 includes a wiring layer 422 and a plurality of recesses 230 and 260 (see FIG. 13) that are recessed from the surrounding surface. The optical element 10 is mounted in the recess 230, and the vertical capacitor 210 is mounted in the recess 260. The relative positions of the optical element 10 and the optical fiber 40 are determined by inserting the pins 450 into the holes 424 formed in the platform 420.
[0133]
The recess 230 has first to third bottom surfaces 232, 234, and 238 (see FIG. 13). The first to third bottom surfaces 232, 234, and 238 are provided in a plurality of stages so that the concave portion 230 becomes wider in the opening direction. Specifically, the first bottom surface 232 is the lowermost bottom surface, the second bottom surface 234 is provided above the first bottom surface 232, and the third bottom surface 238 is further provided above the second bottom surface 234. ing. A hole 236 into which the adhesive 18 enters is formed in the first bottom surface 232, and the optical element 10 is mounted thereon. The first electrode 14 of the optical element 10 is electrically connected to the portion of the wiring layer 422 formed on the second bottom surface 234 by a wire 74. The second bottom surface 234 may be formed around the first bottom surface 232 in a plan view from the opening side of the recess 30 as shown in FIG. It may be formed only on the electrode 14 side.
[0134]
A lens unit 80 is provided inside the recess 230 of the platform 420. The lens unit 80 is disposed above the optical portion 12. Although the shape of the lens part 80 is not limited, For example, it may be plate shape and it may be formed so that it may have a convex shape in the center part. In that case, the central portion of the lens portion 80 is disposed above the optical portion 12. The light intensity distribution between the optical portion 12 and the core 42 of the optical fiber 40 can be matched by the lens unit 80. In particular, when a plastic fiber is used as the optical fiber 40, since the diameter of the core 42 is large, it is preferable to provide the lens unit 80 on the light receiving element side.
[0135]
In the example shown in FIG. 15, the end of the lens unit 80 is placed on the third bottom surface 238 (see FIG. 13), so that the center of the lens unit 80 is disposed above the optical portion 12. Here, the third bottom surface 238 may be formed around the first and second bottom surfaces 232 and 234 in a plan view from the opening side of the recess 230. In that case, the lens unit 80 may be placed on the third bottom surface 238 so as to close the recess 230. Alternatively, the lens unit 80 may be placed on the third bottom surface 238 so as not to block the concave portion 230. The third bottom surface 238 is preferably a surface parallel to the surface having the optical portion 12 of the optical element 10. If necessary, a resin (not shown) may be provided in the recess 230, and the lens unit 80 may be bonded and fixed to the platform 420 with the resin.
[0136]
As shown in FIG. 15, a fixing portion 452 for fixing the pin 450 is formed at the end of the optical fiber 40. The fixing portion 452 is fitted in a recess 440 formed in the platform 420. Here, the recess 440 has a plurality of recesses 230 and 260 inside. In other words, the recess 440 has an outer periphery with a size including a plurality of recesses 230 and 260 and is formed to communicate with the recesses 230 and 260. The recess 440 may have the same form as the form used as the guided portion shown in the above-described embodiment. That is, the fixing portion 452 may be attached to the recess 440 serving as a guided portion as the guide portion shown in the above-described embodiment.
[0137]
A conductive film 454 may be formed on the fixing portion 452 on the side facing the recess 440. The conductive film 454 is as described in the above-described embodiment, and is formed as a wiring pattern as necessary. In the example illustrated in FIG. 15, both the first electrode 212 and the wiring layer 422 of the capacitor 210 are electrically connected by a conductive film 454. If the conductive film 454 is formed on the flat surface of the fixing portion 452, the conductive film 454 is difficult to be disconnected. When the optical element 10 is not provided with the lens portion 80, the first electrode 14 of the optical element 10 and the wiring layer 422 are electrically connected through the conductive film 454 formed in the fixing portion 452. May be.
[0138]
Note that a second electrode 214 is formed on the surface of the capacitor 210 on the side facing the bottom surface of the recess 260, and is electrically connected to a portion of the wiring layer 422 formed on the bottom surface of the recess 260. By providing the capacitor 210, it is possible to prevent the value of the power supply voltage for driving the optical element 10 from being changed by noise.
[0139]
In the method for manufacturing an optical module according to the present embodiment, as shown in FIG. 13, optical element 10 is mounted in recess 230 and capacitor 210 is mounted in recess 260. Then, as shown in FIG. 14, the lens portion 80 is disposed above the optical portion 12 of the optical element 10, the pin 450 is inserted into the hole 424 of the platform 420, and the optical fiber 40 is connected to the optical portion 12. Align. In addition, as shown in FIG. 15, the fixing portion 452 may be fitted into the recess 440 so as to close the concave portions 230 and 260. Note that in the example shown in FIG. 15, electrical connection between the first electrode 212 of the capacitor 210 and the wiring layer 320 is achieved by a conductive film 454 formed in the fixed portion 452.
[0140]
(Sixth embodiment)
FIG. 16 is a diagram showing an optical transmission apparatus according to a sixth embodiment to which the present invention is applied. The optical transmission device 500 includes the form of the optical module described above, and the optical element 10 is provided on each end face 46 of the optical fiber 40 with the optical portion 12 facing. Specifically, a light emitting element is provided on one end face of the optical fiber 40 so that the light emitting section faces, and a light receiving element is provided on the other end face facing the light receiving section. The light emitting element is mounted in a recess formed in the first platform, and the light receiving element is mounted in a recess formed in the second platform. Further, as described above, the optical fiber 40 and the optical element 10 (light emitting element or light receiving element) are attached to the guided part provided on the platform, with the guide part provided at the end of the optical fiber 40 being attached. Is aligned.
[0141]
The optical transmission device 500 connects electronic devices 502 such as a computer, a display, a storage device, and a printer to each other. The electronic device 502 may be an information communication device. The optical transmission device 500 may be one in which plugs 506 are provided at both ends of the cable 504. The cable 504 includes one or more optical fibers 40. The plug 506 may incorporate the platform described in the above embodiment. The plug 506 may incorporate an electronic component.
[0142]
The electric signal output from one electronic device 502 is converted into an optical signal by the optical element 10 which is a light emitting element. The optical signal travels through the optical fiber 40 and is input to the other optical element 10. The optical element 10 is a light receiving element, and an input optical signal is converted into an electric signal. The electric signal is input to the other electronic device 502. Thus, according to the optical transmission device 500 according to the present embodiment, information transmission of the electronic device 502 can be performed by an optical signal.
[0143]
(Seventh embodiment)
FIG. 17 is a diagram illustrating a usage pattern of the optical transmission device according to the seventh embodiment to which the present invention is applied. The light transmission device 512 connects the electronic devices 510. As the electronic device 510, a liquid crystal display monitor or a digital CRT (may be used in the fields of finance, mail order, medical care, education), a liquid crystal projector, a plasma display panel (PDP), a digital TV, a retail store A cash register (for POS (Point of Sale Scanning)), a video, a tuner, a game device, a printer, and the like can be given.
[Brief description of the drawings]
FIG. 1 is a diagram showing a method of manufacturing an optical module according to a first embodiment to which the present invention is applied.
FIG. 2 is a diagram showing an optical module manufacturing method according to the first embodiment to which the present invention is applied.
FIG. 3 is a diagram illustrating an optical module according to a first embodiment to which the present invention is applied.
FIG. 4 is a diagram illustrating a method of manufacturing an optical module according to a second embodiment to which the present invention is applied.
FIG. 5 is a diagram showing a method of manufacturing an optical module according to a second embodiment to which the present invention is applied.
FIG. 6 is a diagram illustrating an optical module according to a second embodiment to which the present invention is applied.
FIG. 7 is a diagram illustrating an optical module manufacturing method according to a third embodiment to which the present invention is applied.
FIG. 8 is a diagram illustrating an optical module manufacturing method according to a third embodiment to which the present invention is applied.
FIG. 9 is a diagram showing an optical module according to a third embodiment to which the present invention is applied.
FIG. 10 is a diagram showing an optical module manufacturing method according to a fourth embodiment to which the present invention is applied.
FIG. 11 is a diagram illustrating a method of manufacturing an optical module according to a fourth embodiment to which the present invention is applied.
FIG. 12 is a diagram showing an optical module according to a fourth embodiment to which the present invention is applied.
FIG. 13 is a diagram showing an optical module manufacturing method according to a fifth embodiment to which the present invention is applied.
FIG. 14 is a diagram showing a method of manufacturing an optical module according to a fifth embodiment to which the present invention is applied.
FIG. 15 is a diagram illustrating an optical module according to a fifth embodiment to which the present invention is applied;
FIG. 16 is a diagram showing an optical transmission apparatus according to a sixth embodiment to which the present invention is applied.
FIG. 17 is a diagram illustrating a usage pattern of a light transmission device according to a seventh embodiment to which the present invention is applied;
[Explanation of symbols]
10 optical elements
12 Optical parts
14 First electrode
16 Second electrode
18 Adhesive
20 platforms
22 Wiring layer
24 holes
30 recess
32 First bottom surface
34 Second bottom surface
36 holes
40 optical fiber
50 pins
52 fixed part
60 recess
62 First bottom surface
64 Second bottom surface
66 holes
70 wires
72 wires
74 wires
80 Lens section
110 Semiconductor chip
120 platform
122 Wiring layer
130 recess
132 First bottom surface
134 Second bottom surface
136 holes
140 depression
150 Guide section
160 recess
162 First bottom surface
166 hole
220 platform
222 Wiring layer
230 recess
232 first bottom surface
234 second bottom surface
236 holes
238 Third bottom surface
240 depression
250 guide section
260 recess
320 platform
322 Wiring layer
340 depression
350 Guide part
352 conductive film
420 platform
422 wiring layer
424 holes
440 depression
450 pins
452 Fixed part
454 conductive film
500 Light transmission device
506 plug
512 Optical transmission device

Claims (3)

A first step of mounting an optical element having an optical part on one side in a recess provided on a platform and having a depth equal to or greater than the thickness of the optical element;
A second step of aligning the optical waveguide and the optical portion by attaching a guide portion provided around the end face of the optical waveguide to a guided portion provided in the platform;
Including
A wiring layer is formed on the platform,
The optical element is formed with a first electrode formed on the surface side having the optical portion, and a second electrode formed on the opposite side of the surface having the optical portion,
In the first step, the second electrode is electrically connected to the wiring layer by a conductive adhesive,
The manufacturing method of the optical module which electrically connects the said 1st electrode to the said wiring layer by the electrically conductive film around the end surface of the said optical waveguide at the said 2nd process. In the manufacturing method of the optical module of Claim 1,
The guide portion is a pin protruding in the axial direction of the optical waveguide from the end surface of the optical waveguide,
The guided portion is a hole formed avoiding the concave portion,
A method for manufacturing an optical module, wherein the pin is inserted into the hole in the second step. In the manufacturing method of the optical module of Claim 1,
The guided portion is a depression,
The recess is provided inside the recess;
In the second step, an optical module manufacturing method in which the guide portion is fitted in the recess.

Images