Source: https://patents.google.com/patent/US7111992
Timestamp: 2018-03-20 15:59:08
Document Index: 166629619

Matched Legal Cases: ['art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 140', 'art 940', 'art 740', 'arts 740', 'art 140', 'art 140', 'art 140', 'art 840', 'art 840', 'art 140', 'art 840', 'art 840', 'art 140', 'art 840', 'art 840', 'art 840', 'art 240', 'art 240', 'art 240', 'art 240', 'art 140', 'art 240', 'art 840', 'art 240', 'art 240', 'art 240', 'art 140', 'art 240', 'art 140', 'art 240', 'art 240', 'art 240', 'art 240', 'art 240', 'art 240', 'art 340', 'art 240', 'art 240', 'art 240', 'art 240', 'art 240', 'art 240', 'art 240', 'art 340', 'art 340', 'art 340', 'art 240', 'art 340', 'art 240', 'art 340', 'art 340', 'art 240', 'art 340', 'art 340', 'art 340', 'art 340', 'art 240', 'art 240', 'art 240', 'art 12', 'art 12', 'art 12', 'art 12', 'art 240', 'art 12', 'art 12', 'art 12', 'art 240', 'art 240', 'art 240', 'art 240', 'art 240', 'art 240', 'art 240', 'art 240', 'art.\n7']

US7111992B2 - Connection structure between optical element and optical fiber, connection method thereof, and optical module - Google Patents
Connection structure between optical element and optical fiber, connection method thereof, and optical module Download PDF
US7111992B2
US7111992B2 US10731105 US73110503A US7111992B2 US 7111992 B2 US7111992 B2 US 7111992B2 US 10731105 US10731105 US 10731105 US 73110503 A US73110503 A US 73110503A US 7111992 B2 US7111992 B2 US 7111992B2
US10731105
US20040156597A1 (en )
The invention provides a connection structure between an optical element and an optical fiber, which makes it possible to inexpensively secure optical transmission between the optical element and the optical fiber. A connection structure of an optical element and an optical fiber of the present invention including an optical element including an optical surface, an optical fiber, and a connecting part coupled to an end surface of the optical fiber and the optical surface.
The present invention relates to a connection structure between an optical element and an optical fiber, and a connection method of coupling an optical element and an optical fiber. Furthermore, the present invention relates to an optical module and an optical transmission unit including the connection structure.
The related art includes developments in optical communication technologies to service high-speed and large-amount data transmission in the information and communication technology sector. In related art optical communications, an electrical signal is usually converted into an optical signal, which is transmitted through optical fibers. Then, the optical signal received is converted into an electrical signal. Such a converting operation from the electrical signal to the optical signal and then from the optical one to the electrical one is performed by optical elements. For implementation of optical communications by such a converting method, it is needed to precisely align the optical fiber and the optical element for the purpose of reducing optical loss.
The invention also provides a connection method of coupling an optical element and an optical fiber that is superior in productivity and does not require accurate alignment between the optical element and the optical fiber.
(1) A connection structure in one aspect of the present invention includes an optical element having an optical surface, an optical fiber, and a connecting part that joins an end surface of the optical fiber and the optical surface.
In this case, at least a part of the end surface of the optical fiber is positioned to face the optical surface.
(2) A connection structure in another aspect of the present invention includes an optical element having an optical surface, an optical fiber having a core and a clad, and a connecting part that joins an end surface of the core and the optical surface.
In this case, at least a part of the end surface of the core is positioned to face the optical surface.
There is no specific restriction on the shape of the end surface of the optical fiber as long as the connecting part is provided. The end surface may be round or oval in shape. Likewise, there is no specific restriction on the sectional shape of the connecting part.
The connection structure of the present invention having such a structure as described above can provide a connection structure between an optical element and an optical fiber that makes it possible to inexpensively secure optical transmission between the optical element and the optical fiber.
Also, in an exemplary embodiment of the invention, there is no specific restriction on the material of the optical fiber. For example, the present invention is applied to any optical fiber of quartz glass, plastic, a complex material of plastic and quartz, and multicomponent glass.
(3) In the connection structure according to the invention, the refractive index of the connecting part is almost equal to the refractive index of the core of the optical fiber. With this structure, light reflection at a boundary between the connecting part and the core can be reduced so that optical loss at the boundary can be reduced.
(4) Also, in the connection structure according to the invention, the refractive index of the connecting part is greater than the refractive index of the clad of the optical fiber.
(5) Also, in the connection structure according to the invention, the height of the end surface of the core is different from the height of the end surface of the clad at the end part of the optical fiber joined to the connecting part.
(i) In this case, the core is not covered by the clad at the end part. This setup makes it possible to form a convex portion by the core and clad at the end part.
An area surrounding the connecting part is covered by a sealant at the end part. With this structure, the connecting part can surely be fixed onto the end surface of the core. As a result, it becomes possible to obtain the connection structure with a higher yield.
In this case, the refractive index of the sealant is smaller than the refractive index of the core of the optical fiber and the refractive index of the connecting part.
Also, in this case, the refractive index of the connecting part is almost equal to the refractive index of the core of the optical fiber, and the refractive index of the sealant is almost equal to the refractive index of the clad of the optical fiber. With this structure, the connecting part and the sealant is provided with similar functions to those of the core and the clad of the optical fiber, respectively. Accordingly, the optical loss can be reduced.
(ii) Moreover, in this case, it is possible to have the clad not cover the core at the end part. Accordingly, a concave portion is formed by the core and clad at the end part. With this structure, the connecting part can surely be fixed onto the end surface of the core. As a result, it becomes possible to obtain the connection structure with a higher yield.
(6) In the connection structure according to the invention, the connecting part is formed by hardening a liquid material that is hardened by charging energy.
In this case, the connecting part is composed of ultraviolet curing resin.
(7) In the connection structure according to the invention, the optical element is any of a surface emitting semiconductor laser, a semiconductor light emitting diode, an electroluminescent (EL) device and a photo diode.
(8) An optical module according to the invention includes the connection structure of the invention and a semiconductor chip that is electrically coupled to the optical element.
The optical module of the present invention having the connection structure makes it possible to configure a connection structure between an optical element and an optical fiber that can secure optical transmission between the optical element and the optical fiber. In comparison with an ordinary optical module in which a lens is additionally placed between the optical fiber and optical element, the optical module of the present invention requires an alignment between the optical fiber and optical element via the connecting part so that the alignment work can be simplified. Furthermore, the connection structure directly connecting the optical element and the optical fiber via the connecting part makes any highly precise alignment unnecessary. Consequently it becomes possible to realize a simplified, downsized and low-cost unit.
(9) An optical transmission unit of the present invention includes an optical fiber, and a light emitting element that has an emitting plane and lets a light emitted from the emitting plane into an end surface of the optical fiber. The optical transmission unit also includes a semiconductor chip electrically coupled to the light emitting element, a light receiving element that has a plane of incidence and introduces a light emitted from the other end surface of the optical fiber through the plane of incidence, and a semiconductor chip electrically coupled to the light receiving element. At least one of the connection structure between the light emitting element and the optical fiber, and the connection structure between the light receiving element and the optical fiber, is the connection structure according to an exemplary embodiment of the present invention, which is described above.
(10) A connection method of coupling an optical element and an optical fiber in one aspect of the present invention includes: (a) forming a connecting part precursor by applying a liquid agent to at least one of an end surface of the optical fiber and an optical surface of the optical element, and (b) forming a connecting part by hardening the connecting part precursor while joining the end surface of the optical fiber and the optical surface via the connecting part precursor.
In this case, step (b) can include joining the end surface of the optical fiber and the optical surface via the connecting part precursor while making at least a part of the end surface of the optical fiber face the optical surface.
The connection method of coupling an optical element and an optical fiber of the present invention achieves high productivity. Moreover, a precise alignment between the optical element and the optical fiber is not required any more. In addition, a simplified method is available to join the optical element and the optical fiber via the connecting part.
(11) A connection method of coupling an optical element and an optical fiber in another aspect of the present invention includes: (a) forming a connecting part precursor by applying a liquid agent to at least one of an end surface of the core of the optical fiber and an optical surface of the optical element, and (b) forming a connecting part by hardening the connecting part precursor while joining the end surface of the core and the optical surface via the connecting part precursor.
In this case, step (b) can include joining the end surface of the core and the optical surface via the connecting part precursor while making at least a part of the end surface of the core face the optical surface.
Also, in this connection method of coupling an optical element and an optical fiber, the height of the end surface of the core is different from the height of the end surface of the clad.
The connection method for coupling an optical element and an optical fiber of the present invention achieves high productivity. Moreover, a precise alignment between the end surface and the optical surface is not required any more. In addition, a simplified method is available to join the optical element and the optical fiber via the connecting part.
(12) In the connection method for coupling an optical element and an optical fiber of the invention, the liquid agent is applied by means of an ink-jet method in which the liquid agent is dispensed by using an ink-jet heads. In this method, the dispensing volume of the liquid agent is precisely adjusted. Therefore, it becomes possible to precisely place a connecting part precursor onto at lease one of the end surface of the optical fiber and the optical surface.
(13) In the connection method for coupling an optical element and an optical fiber of the invention, the connecting part precursor is hardened by charging energy.
(14) In the connection method for coupling an optical element and an optical fiber of the invention, the optical element is any of a surface emitting semiconductor laser, a semiconductor light emitting diode, an EL device and a photo diode.
FIG. 1 is a schematic side view of a connection structure between an optical element and an optical fiber according to a first embodiment of the invention;
FIG. 2 is a schematic that shows a process of a connection method of coupling an optical element and an optical fiber according to the first exemplary embodiment of the invention;
FIG. 3 is a schematic that shows a process of a connection method of coupling an optical element and an optical fiber according to the first exemplary embodiment of the invention;
FIG. 4 is a schematic that shows a process of a connection method of coupling an optical element and an optical fiber according to the first exemplary embodiment of the invention;
FIG. 5 is a schematic side view of a connection structure between an optical element and an optical fiber according to a second exemplary embodiment of the invention;
FIG. 6 is a schematic that shows a process of a connection method of coupling an optical element and an optical fiber according to the second exemplary embodiment of the invention;
FIG. 7 is a schematic that shows a process of a connection method of coupling an optical element and an optical fiber according to the second exemplary embodiment of the invention;
FIG. 8 is a schematic side view of a connection structure between an optical element and an optical fiber according to a third exemplary embodiment of the invention;
FIG. 9 is a schematic that shows an example of a manufacturing process for an optical fiber illustrated in FIG. 8;
FIG. 10 is a schematic that shows an example of a manufacturing process for an optical fiber illustrated in FIG. 8;
FIG. 11 is a schematic that shows a process of a connection method of coupling an optical element and an optical fiber according to the third exemplary embodiment of the invention;
FIG. 12 is a schematic that shows an exemplary modification of a connection structure between an optical element and an optical fiber according to the third exemplary embodiment of the invention;
FIG. 13 is a schematic that shows a connection method of coupling an optical element and an optical fiber of an exemplary modification illustrated in FIG. 12;
FIG. 14 is a schematic that shows an exemplary modification of a connection structure between an optical element and an optical fiber according to the third exemplary embodiment of the invention;
FIG. 15 is a schematic side view of a connection structure between an optical element and an optical fiber according to a fourth exemplary embodiment of the invention;
FIG. 16 is a schematic that shows a process of a connection method of coupling an optical element and an optical fiber according to the fourth exemplary embodiment of the invention;
FIG. 17A is a schematic that shows an exemplary modification of a connection structure between an optical element and an optical fiber according to the first exemplary embodiment, and FIG. 17B is a schematic that shows another exemplary modification of a connection structure between an optical element and an optical fiber according to the first exemplary embodiment of the invention;
FIG. 18 is a schematic that shows an optical module according to a fifth exemplary embodiment of the invention;
FIG. 19 is a schematic that shows an optical communication system according to a sixth exemplary embodiment of the invention;
FIG. 20 is a schematic that shows an implementation format of an optical communication system according to a seventh exemplary embodiment of the invention.
The following sections describe exemplary embodiments of the present invention while referring to the drawings.
1. Connection Structure Between Optical Element and Optical Fiber:
FIG. 1 shows a side view of a connection structure between an optical element and an optical fiber according to a first exemplary embodiment of the present invention. A connection unit 1000 is indicated in FIG. 1 as the connection structure.
The connection unit 1000 includes an optical element 100, an optical fiber 120, and a connecting part 140, as shown in FIG. 1. Each component of the connection unit 1000 is be described below.
The optical element 100 is a light emitting element or a light receiving element. For example, the optical element 100 is a light emitting element to emit light in a direction perpendicular to a substrate, or it is a light receiving element to introduce a light coming in a direction perpendicular to a substrate. When the optical element 100 is a light emitting element, the light emitted from an optical surface 180 is introduced into the optical fiber 120 through the connecting part 140 with high efficiency. If the optical element 100 is a light receiving element, the light emitted from the optical fiber 120 is introduced via the optical surface 180 through the connecting part 140 with high efficiency. There is no specific restriction on the specifications of the optical element 100. The optical element 100 is, for example, any of a surface emitting semiconductor laser, a semiconductor light emitting diode, an EL device and a photo diode.
The optical element 100 includes the optical surface 180. This exemplary embodiment shows an example where the optical surface 180 is placed on the top surface of a column section 130. For example, if the optical element 100 is a surface emitting semiconductor laser, the column section 130 constitutes a part of a resonator. If the optical element 100 is a light emitting diode, the column section 130 includes an active layer.
The optical element 100 is coupled to the optical fiber 120 through the connecting part 140 as shown in FIG. 1. Namely, the relative position of the optical element 100 to the optical fiber 120 is fixed by the connecting part 140. In the connection unit 1000, the optical surface 180 of the optical element 100 is facing at least a part of an end surface 120 a of the optical fiber 120.
The optical fiber 120 generally includes a core 122 and a clad 124. The clad 124 surrounds the core 122 concentrically. In the optical fiber 120, light is reflected at a boundary between the core 122 and the clad 124 so that the light is confined in the core 122 to get transmitted inside the core 122. Meanwhile, the clad 124 is covered and protected by a jacket (not shown).
Though this exemplary embodiment shows an example where the optical fiber 120 has its sectional shape of a circle, there is no specific restriction on the sectional shape of the optical fiber 120. This notice can also be applied to any optical fibers shown in other exemplary embodiments as well as exemplary modifications described below. For example, the optical fiber 120 can be an optical fiber having its sectional shape of an oval, or even another optical fiber which has its sectional core shape of a circle or oval with its sectional clad of any shape.
FIG. 1 shows an end part of the optical fiber 120 (one of the two end parts). It is still possible that each of both the end parts of the optical fiber 120 is equipped with the optical element 100 through the connecting part 140. In this case, the optical element 100 placed at one end part is a light emitting element and placed at another is a light receiving element. Otherwise, it is also possible that only one of the two end parts of the optical fiber 120 is equipped with the optical element 100 through the connecting part 140. This notice can also be applied to any connection structures of optical elements and optical fibers shown in other exemplary embodiments as well as exemplary modifications described below.
(Connecting Part)
As FIG. 1 shows, the connecting part 140 is coupled to the end surface 120 a of the optical fiber 120, and the optical surface 180 of the optical element 100.
When the light emitted from the optical fiber 120 is, for example, let in a light receiving element (not shown), the light emitted from the end surface 120 a of the optical fiber 120 is let in the light receiving element after going through the connecting part 140. When the light emitted from a light emitting element (not shown) is, for example, let in the end surface 120 a of the optical fiber 120, the light emitted from the light emitting element is let in the end surface 120 a of the optical fiber 120 after going through the connecting part 140.
The connecting part 140 is formed by hardening a liquid material that is hardened by charging energy. As the liquid material, for example, a precursor of an ultraviolet curing resin material or a thermosetting resin material is used. As the ultraviolet curing resin material, for example, acrylic base resin and epoxy base resin of an ultraviolet curing type is listed. As the thermosetting cure resin material, polyimide base resin of a thermosetting cure type is named.
A precursor of an ultraviolet cure resin material gets hardened by applying ultraviolet rays for a short time. Therefore, hardening can be done without going through any process, which is likely to cause damage to an element, such as a thermal treatment process. Consequently, forming the connecting part 140 with a precursor of an ultraviolet cure resin material can reduce the chance of any adverse effects on the element.
Specifically, the connecting part 140 is formed by applying a liquid agent to at least one of the end surface 120 a of the optical fiber 120 and the optical surface 180 of the optical element 100 to make a connecting part precursor (described below), and then by hardening the connecting part precursor.
Specifically, the connecting part 140 is composed of a precursor of an ultraviolet cure resin material or a thermosetting cure resin material. In this case, the shape and size of the connecting part 140 is controlled by adjusting the type and volume of the liquid agent to be used to form the connecting part 140. The shape and size of the connecting part 140 is determined according to the distance between the end surface 120 a of the optical fiber 120 and the optical surface 180. Namely, depending on the distance between the end surface 120 a of the optical fiber 120 and the optical surface 180, the shape and size of the connecting part 140 is determined so as to join the end surface 120 a of the optical fiber 120 and the optical surface 180. This notice is also applied to any other exemplary embodiments as well as exemplary modifications described below.
Furthermore, the refractive index of the connecting part 140 is almost equal to the refractive index of the core 122 of the optical fiber 120. With this structure, the light reflection at the boundary between the connecting part 140 and the core 122 can be decreased so that the optical loss at the boundary can be reduced. This notice is also applied to any other exemplary embodiments as well as exemplary modifications described below.
2. Connection Method for Coupling Optical Element and Optical Fiber:
A method of manufacturing the connection unit 1000 shown in FIG. 1 is described below by referring to FIG. 2 and FIG. 3. Each of FIG. 2 through FIG. 4 schematically illustrates each single step of the connection method of coupling the optical element 100 and the optical fiber 120.
(Forming Connecting Part Precursor)
At first, a connecting part precursor is formed on the end surface 120 a of the optical fiber 120 and the optical surface 180. Specifically, a drop of the liquid material (hereinafter a “droplet” 140 b) to form the connecting part 140 is dispensed onto, at lease one of the end surface 120 a of the optical fiber 120 and the optical surface 180 of the optical element 100 so as to form the connecting part precursor (Refer to FIG. 2). As described above, the liquid material is hardened by charging energy.
This exemplary embodiment describes an example where, as shown in FIG. 2, the droplet 140 b is dispensed onto both the end surface 120 a of the optical fiber 120 and the optical surface 180 to form connecting part precursors 140 x and 140 y (Refer to FIG. 3). As a second exemplary embodiment describe below, it is still possible to dispense the droplet 140 b onto either of the end surface 120 a of the optical fiber 120 or the optical surface 180 to form a connecting part precursor and then face the end surface 120 a and optical surface 180 each other to form the connecting part precursor 140 a (described below, refer to FIG. 4).
As a way of dispensing the droplet 140 b, for example, a dispenser method or an ink-jet method is named. The dispenser method is an ordinary way to be used to dispense the droplet 140 b, and it is effective to dispense the droplet 140 b on a relatively wide area.
The ink-jet method is a way of dispensing a droplet by using an ink-jet head. Using this method makes it possible to control a position to which the drop is dispensed at the micrometer level and to control the volume of the drop to be dispensed at the picoliter level. As a result, it becomes possible to manufacture a connecting part of a fine structure on an end surface of an optical fiber that is minute in size.
A way of dispensing the droplet 140 b by using an ink-jet head 110 is described below by referring to FIG. 2. The droplet 140 b is dispensed onto the end surface 120 a of the optical fiber 120 and the optical surface 180 by using the ink-jet head 110 as FIG. 2 shows. As a result, the connecting part precursor 140 y is formed on the end surface 120 a of the optical fiber 120, while the connecting part precursor 140 x is formed on the optical surface 180 as FIG. 3 shows.
Exemplary ways of ink-jet dispensing, including the following two methods described below:
(ii) A piezoelectric element is used to cause pressure, which eventually dispenses the liquid. In order to effectively control liquid pressure, method (ii) is preferable.
A related art or known image recognition technology which is commonly used in an exposure and an inspection work step of semiconductor IC circuit manufacturing processes is applied for alignment work to control the position of an ink-jet head nozzle and the position to which a droplet is dispensed. For example, the alignment is done between the positions of a nozzle 112 of the ink-jet head 110 and the optical surface 180, and the nozzle 112 and the end surface 120 a of the optical fiber 120. After the alignment, the voltage to be imposed onto each ink-jet head is adjusted and then the droplet 140 b is dispensed. As a result of the above operation, the connecting part precursors 140 x and 140 y are formed on the optical surface 180 and the end surface 120 a of the optical fiber 120, respectively, as FIG. 3 shows.
In this exemplary embodiment, the optical element 100 includes the column section 130. The optical surface 180 is provided on the top surface of the column section 130. Consequently, the connecting part precursor 140 x is formed on the top surface of the column section 130. When the droplet 140 b is dispensed onto the optical surface 180, the droplet 140 b remains on the top surface of the column section 130 due to surface tension. As a result, the connecting part precursor 140 x is formed, having the required shape and size.
Meanwhile, the connecting part precursor 140 y is formed on the end surface 120 a of the optical fiber 120. In the same manner as described above; when the droplet 140 b is dispensed onto the end surface 120 a, the droplet 140 b remains on the end surface 120 a due to surface tension. As a result, the connecting part precursor 140 y is formed, having the required shape and size.
Dispensing the droplet 140 b is repeated as many times as needed, to form the connecting part precursors 140 x and 140 y of the required shape and size. The connecting part precursors 140 x and 140 y are so shaped and sized that at least some parts of them meet each other to get joined when the end surface 120 a of the optical fiber 120 and the optical surface 180 are set to have a predetermined distance.
If needed, lyophilic or lyophobic treatment is done for the end surface 120 a of the optical fiber 120 and the optical surface 180 before dispensing the droplet 140 b. This makes it possible to control the wettability of the end surface 120 a and the optical surface 180 for the droplet 140 b. This operation enables controlling the shape and size of the connecting part 140 more precisely.
Next, the end surface 120 a of the optical fiber 120 and the optical surface 180 are faced each other. In this embodiment, at least a part of the end surface 120 a is faced to the optical surface 180. In terms of efficient utilization of light, it is desirable to place the optical fiber 120 and the optical surface 180 as shown in FIG. 4 so that the center of the optical surface 180 is positioned on a line R1 that comes through the center of the end surface 120 a and is perpendicular to the end surface 120 a.
Furthermore, the end surface 120 a of the optical fiber 120 and the optical surface 180 are closely placed to have a predetermined distance between them, and thereby the connecting part precursors 140 x and 140 y (Refer to FIG. 3) get contacted each other. According to this operation, the connecting part precursors 140 x and 140 y, both of which are liquid, are merged into the connecting part precursor 140 a (Refer to FIG. 4). The connecting part precursor 140 a obtained in this step is joined to the end surface 120 a and the optical surface 180, as shown in FIG. 4.
(Forming Connecting Part)
Next, the connecting part precursor 140 a is hardened to form the connecting part 140, as FIG. 4 shows. Specifically, some energy 113 such as thermal energy and optical energy is applied to the connecting part precursor 140 a.
For hardening the connecting part precursor 140 a, an appropriate hardening method is to be selected depending on the type of the liquid material. Specifically, charging thermal energy and radiating ultraviolet rays, laser beams and so on is named as a hardening method. The amount of energy 113 to be charged is adjusted as required, depending on the shape, size and material of the connecting part precursor 140 a. Through the manufacturing steps described above, the connection unit 1000 including the optical element 100, the optical fiber 120, and the connecting part 140 is finally materialized (Refer to FIG. 1).
3. Operation and Effects:
By applying the connection structure between an optical element and an optical fiber according to this exemplary embodiment, it becomes possible to obtain a connection structure (the connection unit 1000) that inexpensively secure optical transmission between the optical element 100 and the optical fiber 120.
Furthermore, applying the connection method for coupling an optical element and an optical fiber according to this exemplary embodiment achieves high productivity and also makes it unnecessary to implement any accurate alignment between the optical element 100 and the optical fiber 120. The operation and effects described above are explained in detail below.
(1) First, since the end surface 120 a of the optical fiber 120 and the optical surface 180 are coupled through the connecting part 140, the optical loss of the light transmitted between the optical fiber 120 and optical element 100 can be reduced. To explain the reason for the above, an ordinary connecting structure between an optical element and an optical fiber is described below.
In the case of an ordinary connecting structure between an optical element and an optical fiber, no connecting part is formed between the optical element and the optical fiber. Therefore, for the purpose of efficiently letting the light emitted from the optical element into the optical fiber or into the optical element, it is needed to precisely perform alignment between the optical element and the optical fiber. In addition, if the optical element is a light emitting element, sometimes the light emitted from the optical surface is once reflected on the end surface of the optical fiber and then enters the optical surface. Then, there arises a problem that the incident light (returning light) changes properties of the optical element.
Meanwhile, in the case of the connection structure according to this exemplary embodiment (the connection unit 1000), the connecting part 140 is joined between the end surface 120 a of the optical fiber 120 and the optical surface 180. Therefore, even without any precise alignment between the optical element 100 and the optical fiber 120, the light emitted from the optical element 100 (or the optical fiber 120) can be efficiently introduced into the optical fiber 120 (or the optical element 100). Namely, by applying this connection unit 1000, it becomes possible even without any precise alignment to secure optical transmission between the optical element 100 and the optical fiber 120.
Furthermore, since the end surface 120 a of the optical fiber 120 and the optical surface 180 are joined through the connecting part 140, it is possible to prevent the above-mentioned returning light from emerging. This enables the optical element 100 to maintain its properties as they are.
An exemplary modification is shown in FIG. 17A (a connection unit 1100). Even if the center of the optical surface 180 is not positioned on the line R1 that comes through the center of the end surface 120 a of the optical fiber 120 and is perpendicular to the end surface 120 a, it is still possible to efficiently transmit light since the end surface 120 a and the optical surface 180 are joined through a connecting part 940.
Another exemplary modification is shown in FIG. 17B (a connection unit 3100). Even if the center of the optical surface 180 is not positioned on a line R2 that comes through the center of an end surface 222 a of a core 222 and is perpendicular to the end surface 222 a, it is still possible to efficiently transmit light since the end surface 222 a and the optical surface 180 are joined through a connecting part 740.
In FIG. 17A and FIG. 17B, the connecting parts 740 and 940 are made of the same material as that of the connecting part 140 described in this exemplary embodiment, and they are formed by the same method as this exemplary embodiment explains.
(2) Second, the connecting part 140 is formed by hardening a liquid material that is hardened by charging energy. In other words, a connecting part precursor is formed on at least one of the end surface 120 a of the optical fiber 120 or the optical surface 180. Then, while contacting with the end surface 120 a and the optical surface 180, the connecting part precursor is hardened. As a result, the optical element 100 and the optical fiber 120 are joined through the connecting part 140. Accordingly, it is not required to implement any accurate alignment between the optical element 100 and the optical fiber 120.
The shape and size of the connecting part precursor 140 a is controlled by adjusting the dispensing volume of the droplet 140 b. Therefore, the shape and size of the connecting part precursor 140 a can be adjusted according to the distance between the optical element 100 and the optical fiber 120.
The connection unit 2000 includes the optical element 100, the optical fiber 120, and a connecting part 840, as shown in FIG. 5.
In the connection unit 2000, the way of forming the connecting part 840 is different from that of the connecting part 140 (Refer to FIG. 1) described in the first exemplary embodiment. The other structural components other than this point are the same as those of the connection unit 1000 of the first exemplary embodiment. As a general rule in the description on this connection unit 2000, any component having the same structure as the corresponding component in the connection unit 1000 of the first exemplary embodiment is provided with the same symbol as given in the connection unit 1000, and any detailed description for the component is omitted.
Next, a method of manufacturing the connection unit 2000 shown in FIG. 5 is described by referring to FIG. 6 and FIG. 7. For any process which is the same as the connection method for coupling the optical element 100 and the optical fiber 120 of the first exemplary embodiment described above, the relevant description is omitted as a general rule.
A forming method of the connecting part 840 (Refer to FIG. 5) is the same as described in the first exemplary embodiment. Furthermore, the connecting part 840 is made of the same material as that of the connecting part 140 described in the first exemplary embodiment.
Specifically, while the end surface 120 a of the optical fiber 120 and the optical surface 180 are kept to face each other as shown in FIG. 7, the end surface 120 a of the optical fiber 120 and the optical surface 180 are closely placed to have a predetermined distance between them, and then the connecting part precursor 840 a gets contacted with the optical surface 180. Then, the energy 113 is applied to the connecting part precursor 840 a to harden the connecting part precursor 840 a. As a result, the connecting part 840 is formed as FIG. 5 shows.
This exemplary embodiment describes an example where the connecting part 840 is formed by the process in which the connecting part precursor 840 a is formed only on the end surface 120 a of the optical fiber 120. Alternatively, it is also possible to place a connecting part precursor only on the optical surface 180 to form the connecting part (not shown). In this case, the connecting part precursor gets touched with at least the end surface of the core on the end surface 120 a when the connecting part precursor gets touched with the end surface 120 a.
Applying the connection structure and the connection method of coupling an optical element and an optical fiber of this exemplary embodiment brings the same operation and effects that the connection structure and the connection method of the first exemplary embodiment have.
Moreover, by applying the connection structure and the connection method of coupling an optical element and an optical fiber of this exemplary embodiment, the connecting part is formed by the process where a connecting part precursor is formed onto either of the end surface 120 a of the optical fiber 120 and the optical surface 180. Thus, the connecting part is obtained by an easier method.
In particular, when the connecting part precursor 840 a is formed on the end surface 120 a of the optical fiber 120, surface tension generally acts on the connecting part precursor 840 a as far as the side of the optical fiber 120 does not get wet with the connecting part precursor 840 a. Therefore, the shape and size of the connecting part precursor 840 a can be controlled by adjusting the volume of the liquid agent by which the connecting part precursor 840 a is formed. As a result, the connecting part 840 is formed, having the required shape and size.
FIG. 8 shows a side view of a connection structure between an optical element and an optical fiber according to a third exemplary embodiment of the present invention. A connection unit 3000 is shown in FIG. 8 connection structure.
The connection unit 3000 of this exemplary embodiment includes the optical element 100, an optical fiber 220, and a connecting part 240, as shown in FIG. 8.
The connection unit 3000 shown in FIG. 8 has a different structure from the structures of the first and second exemplary embodiments in a point that the height of an end surface 222 a of a core 222 is different from that of an end surface 224 a of a clad 224 at an end part of the optical fiber 220, while the end surface 222 a and the optical surface 180 are joined through the connecting part 240.
Each component of the connection unit 3000 is described below. As a general rule in the description on this connection unit 3000, any component having the same structure as the corresponding component in the connection unit 1000 of the first exemplary embodiment is provided with the same symbol as given in the connection unit 1000, and any detailed description for the component is omitted.
The optical fiber 220 includes the core 222 and the clad 224. This exemplary embodiment shows an example where the core 222 is not covered by the clad 224 at the end part of the optical fiber 220 shown in FIG. 8. The optical fiber 220 exposes an aspect of the core 222. In other words, the end surface 222 a of the core 222 is protruding from the end surface 224 a of the clad 224 at the end part of the optical fiber 220 shown in FIG. 8. Accordingly, the core 222 and the clad 224 forms a convex portion 260.
Furthermore, the optical fiber 220 is made of the same material as that of the optical fiber 120 described in the first exemplary embodiment.
The connecting part 240 is positioned on the end surface 222 a of the core 222 of the optical fiber 220 as FIG. 8 shows. The connecting part 240 is made of the same material as that of the connecting part 140 described in the first exemplary embodiment.
The connecting part 240 is formed by using the same manufacturing method as that of the connecting part 840 (Refer to FIG. 5) described in the second exemplary embodiment. Specifically, the connecting part 240 is formed by applying a droplet onto the end surface 222 a of the core 222 of the optical fiber 220 to make a connecting part precursor (described below) there, and then by hardening the connecting part precursor.
Next, a method of connecting an optical element and an optical fiber shown in FIG. 8 is described by referring to FIG. 9 through FIG. 11. For any process which is the same as that of the connection method of coupling an optical element and an optical fiber of the first exemplary embodiment described above, the relevant description is omitted as a general rule.
(Manufacturing End Surface of Core and Clad)
At first, procedures to protrude the end surface 222 a of the core 222 from the end surface 224 a of the clad 224 are explained below. Specifically, the following methods (1) and (2) are cited as an example to protrude the end surface 222 a of the core 222 from the end surface 224 a of the clad 224.
(1) Wet Etching Method:
In general, a core and a clad of an optical fiber are composed of different component in order to have a greater refractive index of the core than that of the clad. Therefore, by making use of the difference in the components of the core and clad, it is possible to selectively remove either the core or the clad by wet etching.
As an etchant to be used for such a selectively etching operation for the core and clad of a silica-based fiber, for example, a solution prepared by blending hydrofluoric acid and ammonium fluoride (buffer fluoric acid solution) is used. In this case, by adjusting concentrations of hydrofluoric acid and ammonium fluoride in the buffer fluoric acid solution, the clad 224 can selectively be removed.
Specifically, the clad 224 is removed by using a buffer fluoric acid solution prepared by blending a 40wt. % ammonium fluoride solution, a 50wt. % hydrofluoric acid solution, and pure water (H2O) with specified volume ratios.
It is also possible to selectively remove the core 222 by adjusting concentrations of hydrofluoric acid and ammonium fluoride in the buffer fluoric acid solution. This operation is explained in detail in another exemplary embodiment described below.
(2) Photo-Curing Method:
Next, procedures to protrude the core 222 by photo-curing are explained by referring to FIG. 10. In this method, a grow of a photo-curing resin is positioned at the end surface of the core 222 of the optical fiber 220 to protrude the end surface 222 a of the core 222 from the end surface 224 a of the clad 224. In this case, there is no specific restriction on the material of the optical fiber 220 as far as the adherence with the photo-curing resin is secured.
Specifically, an end part (one of the two end parts) of the optical fiber 220 including the end surface 222 a is soaked into a liquid material 232 including a precursor component of an ultraviolet curing resin material as FIG. 10 shows. Meanwhile, at the other end part, ultraviolet rays 213 are let in through an end surface 222 b of the core 222. Then, the ultraviolet rays 213 let in through the end surface 222 b are transmitted inside the core 222, and are emitted from the end surface 222 a of the core 222. In this case, no ultraviolet rays are introduced into the clad 224. Therefore, no ultraviolet rays are emitted from the clad 224, and the end surface 222 a of the core 222 is the only part that emits the ultraviolet rays 213. As a result, by the ultraviolet rays 213 emitted from the end surface 222 a of the core 222, the precursor component of the ultraviolet curing resin material that is included in the liquid material 232 gets reacted at the end surface 222 a of the core 222. According to the above operation, a grow of the ultraviolet curing resin material is formed at the end surface 222 a of the core 222 so that the core 222 becomes elongated. Consequently, the optical fiber 220 is provided with a structure in which the end surface 222 a of the core 222 is protruded from the end surface 224 a of the clad 224 as shown in FIG. 8.
FIG. 10 shows an example where the core 222 becomes elongated while the end part of the optical fiber 220 is soaked into the liquid material 232. Instead of soaking the end part of the optical fiber 220 into the liquid material 232, it is also possible to position the liquid material 232 onto the end surface 222 of the optical fiber 220 and then let in ultraviolet rays through the other end surface of the core 222 to elongate the core 222 in the same manner as FIG. 10 shows. This alternative is not shown in the drawings.
Next, the connecting part 240 is formed on the end surface 222 a of the core 222 of the optical fiber 220. Except the point that the connecting part 240 is formed on the end surface 222 a of the core 222, the method of forming a connecting part in this exemplary embodiment is the same as that of forming the connecting part 140 in the first exemplary embodiment. Furthermore, the connecting part 240 is made of the same material as that of the connecting part 140 described in the first exemplary embodiment.
Specifically, a drop of the liquid material to form the connecting part 240 is dispensed onto the end surface 222 a of the core 222 of the optical fiber 220. As a result, the connecting part precursor 240 a is formed on the end surface 222 a of the core 222 as shown in FIG. 11. While the end surface 222 a of the core 222 and the optical surface 180 are kept to face each other, the end surface 222 a of the core 222 and the optical surface 180 are closely placed to have a predetermined distance between them, and then the connecting part precursor 240 a gets contacted with the optical surface 180. Then, energy is applied to the connecting part precursor 240 a under the conditions described above to harden the connecting part precursor 240 a. As a result, the connecting part 240 is formed (Refer to FIG. 8).
As a method to harden the connecting part precursor 240 a, the same hardening method as that for the connecting part precursor 140 a in the first exemplary embodiment is used. As a result of it, the connection unit of the optical element 100 and the optical fiber 220 (the connection unit 3000) is obtained (Refer to FIG. 8).
Applying a connection structure and a connection method of coupling an optical element and an optical fiber of this exemplary embodiment brings the same operation and effects as the connection structure and the connection method of the first exemplary embodiment.
According to the connection structure and the connection method of coupling an optical element and an optical fiber of this exemplary embodiment, the connecting part 240 is formed on the end surface 222 a of the core 222 of the optical fiber 220. In the optical fiber 220, light is transmitted only inside the core 222. Namely, since the connecting part 240 is positioned only on the end surface 222 a of the core 222, the light is efficiently introduced into the optical element 100 from the core 222 through the connecting part 240, when the optical element 100 is a light receiving element. If the optical element 100 is a light emitting element, the light is efficiently introduced into the core 222 from the optical element 100 through the connecting part 240.
4. Exemplary Modifications:
Exemplary modifications of the connection structure between an optical element and an optical fiber of this exemplary embodiment are explained below.
(1) First Exemplary Modification
FIG. 12 shows a connection structure between an optical element and an optical fiber as an exemplary modification of this exemplary embodiment. FIG. 13 shows a connection method of coupling the optical element and the optical fiber of the modification illustrated in FIG. 12, which shows a connection unit 3200 as the connection structure of the exemplary modification.
For example, in the optical fiber 220 shown in FIG. 13, a convex is formed by the end surface 222 a of the core 222 and the end surface 224 a of the clad 224. In this case, when the connecting part precursor 340 a is formed on the end surface 222 a of the core 222, adjusting the volume of the liquid agent to be used enables the maximum diameter d2 of the connecting part precursor 340 a to become greater than the diameter d1 of the end surface 222 a. According to this operation, the connecting part 340 is made still greater. As a result, when the end surface 222 a of the core 222 and the optical surface 180 of the optical element 100 are coupled, a margin of the distance between the two is set to be greater.
(2) Second Exemplary Modification
FIG. 14 shows a connection structure between an optical element and an optical fiber as an exemplary modification of this exemplary embodiment. FIG. 14 shows a connection unit 3300 as the connection structure between an optical element and an optical fiber.
In the connection unit 3300 shown in FIG. 14; the surrounding area of the protruded section of the core 222, the connecting part 240, and the column section 130 are covered by a sealant 226 at an end part of the connection unit 3000 shown in FIG. 8.
Namely, except the sealant 226, the other structure of connection unit 3300 is the same as that of the connection unit 3000 (Refer to FIG. 8) of this exemplary embodiment. Therefore, the connection unit 3300 is provided with the same operation and effects as the connection unit 3000.
Furthermore, in the connection unit 3300, the surrounding area of the connecting part 240 is covered by the sealant 226, and then the connecting part 240 is surely fixed between the end surface 222 a of the core 222 and the optical surface 180. As a result, a higher yield can be achieved.
In the event, the refractive index of the sealant 226 is preferably lower than those of the core 222 and the connecting part 240. By applying such a structure, the sealant 226 is provided with a function as a clad to confine the light transmitting inside the core 222 and the connecting part 240 at the end part of the optical fiber 220 shown in FIG. 14.
Furthermore, the refractive index of the connecting part 240 is preferred to be the same as that of the core 222, and the refractive index of the sealant 226 is still further preferred to be the same as that of the clad 224. In other word, by applying such a structure, the connecting part 240 and the sealant 226 is provided with the functions of the core and the clad of the optical fiber, respectively. The optical loss can be reduced accordingly.
The descriptions on the refractive indexes mentioned above are also applied to the other exemplary embodiments and exemplary modifications.
There is no specific restriction on the material of the sealant 226. For example, a resin material of an ultraviolet cure resin type or a thermosetting cure resin type is used.
1. Connection Structure Between an Optical Element and an Optical Fiber:
The connection unit 4000 of this exemplary embodiment includes the optical element 100, an optical fiber 320, and the connecting part 340 as shown in FIG. 15.
Meanwhile, in the connection unit 4000 of this exemplary embodiment, the clad 324 does not cover the core 322 at an end part of the optical fiber 320 as FIG. 15 shows. In terms of the point described above, the connection unit 4000 is provided with a structure that is different from the structure of the third exemplary embodiment. In other words, an inner wall of the clad 324 exposes it.
Next, each component of the connection unit 4000 is described below. However, as a general rule in the description on the connection unit 4000, any component having the same structure as the corresponding component in the connection unit 3000 of the third exemplary embodiment (Refer to FIG. 8) is provided with the same symbol as given in the connection unit 3000, and any detailed description for the component is omitted.
The optical fiber 320 includes the core 322 and the clad 324. This exemplary embodiment shows an example where the clad 324 does not cover the core 322 at the end part of the optical fiber 320 as mentioned above. In other words, the end surface 324 a of the clad 324 is protruding from the end surface 322 a of the core 322 at the end part of the optical fiber 320 as shown in FIG. 15 so that a concave portion 360 is composed there of the core 322 and the clad 324.
The optical fiber 320 is made of the same material as that of the component mentioned as the optical fiber 120 in the first exemplary embodiment.
The connecting part 340 is positioned on the end surface 322 a of the core 322 of the optical fiber 320 as FIG. 15 shows. The connecting part 340 is made of the same material as that of the connecting part 240 (Refer to FIG. 8) described in the third exemplary embodiment.
Furthermore, the connecting part 340 is formed by using the same manufacturing method as that for the connecting part 240 described in the third exemplary embodiment. Specifically, the connecting part 340 is formed by applying a liquid agent onto the end surface 322 a of the core 322 of the optical fiber 320 to make a connecting part precursor (described below) there, and then by hardening the connecting part precursor.
A method of connecting an optical element and an optical fiber shown in FIG. 15 is described by referring to FIG. 16. For any process, which is the same for the connection method of coupling an optical element and an optical fiber of the third exemplary embodiment described earlier, the relevant description is omitted as a general rule.
In this exemplary embodiment, the end surface of the core 322 and the clad 324 of the optical fiber 320 is manufactured by the wet etching method described as one of the methods for the third exemplary embodiment. Specifically, while controlling the types and concentrations of the components, of which the etchant is composed, etching operation is implemented to selectively remove the core 322 by the wet etching method.
Specifically, a solution for the use of removing the clad in the second exemplary embodiment is used, while concentrations of the components in the solution are adjusted.
Next, the connecting part precursor 340 a is formed on the end surface 322 a of the core 322 of the optical fiber 320. In this exemplary embodiment, the method of forming the connecting part 340 is the same as that of forming the connecting part 240 in the third exemplary embodiment. Furthermore, the connecting part precursor 340 a is realized with the same material as that of the connecting part precursor 140 a (Refer to FIG. 4) described in the first exemplary embodiment.
Specifically, a drop of the liquid material to form the connecting part 340 is dispensed onto the end surface 322 a of the core 322 of the optical fiber 320 to form the connecting part precursor 340 a on the end surface 322 a of the core 322 as shown in FIG. 16. While the end surface 322 a of the core 322 and the optical surface 180 of the optical element 100 (Refer to FIG. 15) are kept to face each other, the end surface 322 a of the core 322 and the optical surface 180 are placed to be close each other to have the specified distance between them, and then the connecting part precursor 340 a gets contacted with the optical surface 180. Then, energy is charged to the connecting part precursor 340 a under the conditions described above to harden the connecting part precursor 340 a. As a result of it, the connecting part 340 is formed. According to the above operation, a connection structure between the optical element 100 and the optical fiber 320 (connection unit 4000) is obtained (Refer to FIG. 15).
Applying a connection structure and a connection method for coupling an optical element and an optical fiber of this exemplary embodiment brings the same operation and effects that the connection structure and the connection method of the first exemplary embodiment have.
According to the connection structure and the connection method for coupling an optical element and an optical fiber of this exemplary embodiment, the clad 324 does not cover the core 322 at an end part of the optical fiber 320 as FIG. 15 shows. In other words, the concave portion 360 is composed there of the core 322 and the clad 324. Since the connecting part 340 is positioned at the concave portion 360, the connecting part 340 is surely fixed there. As a result, a higher yield can be achieved.
FIG. 18 graphically shows an optical module 5000 of a fifth exemplary embodiment of the present invention. The optical module 5000 includes, an optical element 10, a semiconductor chip 20, and the optical fiber 220 of the third exemplary embodiment (Refer to FIG. 8).
As FIG. 18 shows, the optical module 5000 of this exemplary embodiment includes a connection structure, which is composed of the optical element 10, the optical fiber 220, and the connecting part 240. Namely, the optical element 10 and the optical fiber 220 are coupled through the connecting part 240.
The optical module 5000 includes the same connection structure as that of the third exemplary embodiment (the connection unit 3000). Specifically, the optical fiber 220 and the connecting part 240 (Refer to FIG. 18) have the same structure as what the connection unit 3000 of the third exemplary embodiment (Refer to FIG. 8) includes. Instead of the optical element 100 (Refer to FIG. 8) that the connection unit 3000 of the third exemplary embodiment includes, the optical element 10 is placed in the optical module 5000 of this exemplary embodiment as FIG. 18 shows.
In this optical module 5000, any of the optical fibers mentioned in the modifications and other exemplary embodiments described above can be used instead of the optical fiber 220.
1. Structure of Optical Module:
The optical element 10 is a light emitting element or a light receiving element. As an example of the light emitting element; a surface emitting element, such as a surface emitting laser in particular is applied. A surface emitting element, such as a surface emitting laser, emits light beams in a direction perpendicular to a substrate. The optical element 10 has an optical part 12. When the optical element 10 is a light emitting element, the optical part 12 is a light emitting part. When the optical element 10 is a light receiving element, the optical part 12 is a light receiving part. Meanwhile, the optical part 12 is provided with an optical surface 12 a.
The optical element 10 is coupled to the optical fiber 220 through the connecting part 240. Meanwhile, the optical part 12 is positioned so as to face the core 222 of the optical fiber 220. Furthermore in this exemplary embodiment, the optical part 12 is positioned so as to face a hole e semiconductor chip 20.
The optical element 10 has at least one electrode (usually two or more electrodes). For example, a first electrode 14 is positioned on a surface of the optical element 10 where the optical part 12 is placed. When the first electrode 14 includes a plurality of first electrodes, at least one electrode is a dummy electrode. The dummy electrode is made of the same material as that of the first electrode 14, and it is not electrically coupled to the internal part of the optical element 10. For example, when the first electrode 14 is formed at the comers on a polygon that has three or more comers and is drawn with all straight lines, at least one of the electrodes is a dummy electrode. With to the structure described above, the optical element 10 can stably be supported with three or more points.
Regarding the optical element 10; while the first electrode 14 being positioned on a surface part of the optical element, a second electrode 16 is positioned on another surface part. When the optical element 10 is a semiconductor laser such as a surface emitting laser or equivalent, the second electrode 16 is positioned on another surface part of the optical element 10 that is opposite to the surface part where the first electrode 14 is positioned.
The semiconductor chip 20 is to operate the optical element 10. A circuit to operate the optical element 10 is embedded in the semiconductor chip 20. On the semiconductor chip 20, multiple electrodes (or pads) 22 are formed and they are electrically coupled to an internal circuit of the chip. On the surface where the electrodes 22 are formed, it is preferred to have a wiring pattern 24 electrically coupled to at least one of the electrodes 22.
The semiconductor chip 20 and the wiring patterns 24 are coupled electrically. For example, the first electrode 14 of the optical element 10 is electrically coupled to the wiring pattern 24 formed on the semiconductor chip 20. Though they are coupled with wire, it is also possible to connect the first electrode 14 and the wiring pattern 24 with metallic connection by a solder section 26 of a brazing material or equivalent or an anisotropic conductive material (film). In this case, the optical element 10 is mounted face-down onto the semiconductor chip 20. With this structure, the solder section 26 does not only connect them electrically but is also able to stably fix the optical element 10 and the semiconductor chip 20. Among the first electrode 14, the dummy electrode is also preferably coupled to the wiring pattern 24. With this structure, the optical element 10 is stably fixed onto the semiconductor chip 20.
Furthermore, the second electrode 16 of the optical element 10 is electrically coupled to the wiring pattern 24. For connecting them, a wire 27 is used or a conductive paste is placed from the second electrode 16 to the wiring pattern 24.
Between the optical element 10 and the semiconductor chip 20, an under-fill material 40 is placed. The under-fill material 40 covers the electrically connecting part between the optical element 10 and the semiconductor chip 20 to protect the connecting part, and it also protects the surfaces of the optical element 10 and the semiconductor chip 20. Furthermore, the under-fill material 40 has a function of retaining the connecting condition between the optical element 10 and the semiconductor chip 20.
In addition, the under-fill material 40 has a function as a sealant to fix the part between the connecting part 240 and the optical fiber 220. The refractive index of the under-fill material 40 is preferably lower than those of the core 222 of the optical fiber 220 and the connecting part 240. By applying such a structure, the under-fill material 40 is provided with a function as a clad to confine the light transmitting inside the core 222 and the connecting part 240.
Furthermore, the refractive index of the connecting part 240 is preferred to be the same as that of the core 222, and the refractive index of the under-fill material 40 is still further preferred to be the same as that of the clad 224. In other word, by applying such a structure, the connecting part 240 and the under-fill material 40 is provided with the functions of the core and the clad of the optical fiber, respectively.
A hole example, a through hole) is formed in the semiconductor chip 20. The optical fiber 220 is inserted into the hole 28, while the connecting part 240 is positioned at the end surface 222 a of the core 222 of the optical fiber 220. The hole 28 goes through from the surface, where the electrodes 22 are formed, to the opposite surface while the hole is keeping clear of any internal circuit. It is preferred that at least either of the hole inlets of the hole taper section 29, with which it becomes easier to insert the optical fiber 220 into the hole 28.
The semiconductor chip 20 is mounted on a substrate 42. Specifically, the semiconductor chip 20 is mounted on the substrate 42 through an adhesive 44. The substrate 42 is provided with a hole 46, which is so placed at a position as to meet the hole 28 of the semiconductor chip 20. The adhesive 44 bonding the semiconductor chip 20 and the substrate 42 together is placed so as not to interfere with the meeting of the two holes, i.e., the holes 28, and 46 not to clog the holes. The hole 46 of the substrate 42 is formed with a taper section that has a larger inner diameter toward the opposite direction away from the semiconductor chip 20. With the taper section, it becomes easier to insert the optical fiber 220.
The substrate 42 is preferably provided with high thermal conductivity. With this structure, the substrate 42 promotes radiation of the heat from at least either of the optical element 10 and the semiconductor chip 20. In this case, the substrate 42 functions as a heat sink or a heat spreader. In this exemplary embodiment, the semiconductor chip 20 is bonded onto the substrate 42, and then the semiconductor chip 20 can be cooled directly. The adhesive 44 bonding the semiconductor chip 20 and the substrate 42 together is preferably provided with thermal conductivity. Furthermore, as the semiconductor chip 20 gets cooled, the optical element 10 coupled to the semiconductor chip 20 is also cooled.
The substrate 42 is provided with a wiring pattern 48 and an external terminal 50. In this exemplary embodiment, the external terminal 50 is a lead. The wiring pattern 48 positioned on the substrate 42 is electrically coupled to at least one of the following components; i.e., the electrodes 22 of the semiconductor chip 20, the wiring pattern 24 placed on the semiconductor chip 20, the first electrode 14 and second electrode 16 of the optical element 10; for example through a wire 52. In this case, the wiring pattern 48 can electrically be coupled to the external terminal 50 as well.
The optical fiber 220 is inserted into the hole 28 of the semiconductor chip 20. The optical surface 12 a of the optical element 10 is facing the hole 28 of the semiconductor chip 20. Therefore, the optical fiber 220 inserted into the hole 28 becomes aligned to the optical surface 12 a.
In this exemplary embodiment, the optical element 10 and the semiconductor chip 20 are sealed with a resin 56, which also seals the electrically connecting parts between the optical element 10 and the semiconductor chip 20, as well as the electrically connecting parts between the semiconductor chip 20 and the wiring pattern 48 positioned on the substrate 42.
2. Operation and Effects:
By applying the optical module 5000 of this exemplary embodiment, the optical element 10 and the optical fiber 220 are coupled through the connecting part 240. Therefore, being compared with an ordinary optical module additionally equipped with a lens between the optical fiber and optical element, applying the optical module 5000 makes it possible to realize a simplified, downsized and low-cost unit.
Furthermore, being compared with an ordinary optical module additionally equipped with a lens between the optical fiber and optical element, applying this optical module 5000 makes it possible to surely secure optical transmission between the optical element 100 and the optical fiber 220 through the connecting part 240.
FIG. 19 shows an optical communication system of an exemplary embodiment of the present invention. An optical transmission unit 90 connects electronic devices 92, such as a computer, a display, a memory device, a printer and so on. The electronic devices 92 can be information technology equipment. The optical transmission unit 90 can be a cable 94 equipped with a plug 96 at each cable end. At lease one of the ends of the cable 94 can be equipped with a connection structure between the optical element 100 and the optical fiber 120 of the first exemplary embodiment (i.e., the connection unit 1000; Refer to FIG. 1). The plug 96 has a semiconductor chip 20 in it. The installation condition of the optical fiber 120 and the optical element 100 or the semiconductor chip 20 is as described above. In this case, instead of the connection structure between the optical element 100 and the optical fiber 120 of the first exemplary embodiment, any connection structure of the modifications and other exemplary embodiments described above can be applied.
The optical element 100 equipped at either end of the optical fiber 120 is a light emitting element. An electric signal output from the electronic devices 92 at one end is converted into an optical signal by the light emitting element of the optical element 100. The optical signal gets transmitted through the optical fiber 120 and is input into the optical element 100 at another end, which is a light receiving element. The input signal is converted into an electric signal, which is sent into the electronic devices 92 at another end. In this manner, using the optical transmission unit 90 of this exemplary embodiment makes it possible to communicate information data between the electronic devices 92 with optical signal.
FIG. 20 shows an implementation format of an optical communication system of an exemplary embodiment of the present invention. The optical transmission unit 90 connects electronic devices 80, as which the following devices are named; i.e., an LCD monitor, or a digital-communication-compatible CRT (which are sometimes used in the business sectors of finance industry, mail-order business, medical industry, and education), an LCD projector, a plasma display panel (PDP), a digital TV, a cash register for retailers (for Point of Sale Scanning (POS)), a VCR, a tuner, a video game machine, a printer and so on.
The present invention is not restricted only to the exemplary embodiments described above, but various other modifications can also be applicable. For example, the present invention includes other structures as well that are practically the same as any structure mentioned above in the descriptions for the exemplary embodiments (For example, a structure in which the function, method and result are the same, or a structure in which the purpose and result are the same). Furthermore, the present invention includes other structures as well in which trivial details of any structure of the exemplary embodiments mentioned above are replaced. In addition, the present invention includes other structures as well that result in the same operation and effects as any structure of the exemplary embodiments mentioned above, or that are able to achieve the same purposes. Moreover, the present invention includes other structures as well in which publicly related art or known technologies are added to any structure of the exemplary embodiments mentioned above.
an optical fiber having a clad and a core, a part of the core being enclosed in the clad, the core having an exposed surface; and
a connecting part that joins the optical surface and only the exposed surface of the core of the optical fiber, the connecting part having a maximum cross section that has a broader region than (1) a connection region between the connecting part and the optical element and (2) a connection region between the connecting part and the optical fiber.
2. The connection structure according to claim 1, wherein the exposed surface has an end surface of the exposed surface of the core of the optical fiber.
3. The connection structure according to claim 1, a refractive index of the connecting part being almost equal to a refractive index of the core of the optical fiber.
4. The connection structure according to claim 1, the refractive index of the connecting part being greater than a refractive index of the clad of the optical fiber.
5. The connection structure according to claim 4, an area that surrounds the connecting part being covered by a sealant at the end surface.
6. The connection according to claim 5, a refractive index of the sealant being smaller than the refractive index of the core of the optical fiber and the refractive index of the connecting part.
7. The connection structure according to claim 6, the refractive index of the connecting part being almost equal to the refractive index of the core of the optical fiber, and the refractive index of the sealant being almost equal to the refractive index of the clad of the optical fiber.
8. The connection structure according to claim 1, the connecting part being formed by hardening a liquid material that is hardened by charging energy.
9. The connection structure according to claim 8, the connecting part being composed of ultraviolet curing resin.
10. The connection structure according to claim 1, the optical element being at least one of a surface emitting semiconductor laser, a semiconductor light emitting diode, an electroluminescent device, and a photo diode.
the connection structure according to claim 1, and
a semiconductor chip electrically coupled to the optical element.
12. An optical transmission unit, comprising:
a light emitting element including an emitting plane, and enabling a light that is emitted from the emitting plane into an end surface of the optical fiber;
a semiconductor chip electrically coupled to the light emitting element;
a light receiving element including a plane of incidence, and introducing a light that is emitted from the other end surface of the optical fiber through the plane of incidence; and
a semiconductor chip electrically coupled to the light receiving element;
the connection structure according to claim 1, the connection structure including at least one of a connection structure between the light emitting element and the optical fiber, and a connection structure between the light receiving element and the optical fiber.
13. The connection structure according to claim 1, wherein the connecting part secures optical transmission between the optical element and the optical fiber without precise alignment of the optical element and the optical fiber.
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US20040156597A1 true US20040156597A1 (en) 2004-08-12
US7111992B2 true US7111992B2 (en) 2006-09-26
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US10731105 Expired - Fee Related US7111992B2 (en) 2003-02-10 2003-12-10 Connection structure between optical element and optical fiber, connection method thereof, and optical module
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