JP4032245B2 - Optical communication system and electronic device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical communication module for transmitting and receiving an optical signal, and more particularly to optically connect an optical transmission line and an optical device that extend in a direction different from the incident and outgoing direction of the optical signal of the optical device. An optical communication module is provided.
[0002]
[Prior art]
The optical communication module includes an optical device such as a light receiving element that converts an optical signal into an electrical signal and a light emitting element that converts an electrical signal into an optical signal, and an optical transmission path that transmits an optical signal transmitted and received by the optical device. An optical communication system is configured by combining these optical devices and optical transmission paths.
[0003]
Conventionally, a flat optical device such as a surface light emitting diode is mounted on a substrate and light is propagated along the substrate surface. Light emitted from the optical device in a direction perpendicular to the substrate surface is reflected by a mirror or the like. The light is reflected at right angles by the means and incident on the end face of the optical fiber.
[0004]
For example, Japanese Patent Application Laid-Open No. 2001-141965 discloses a technique in which an elliptical curved mirror is provided on a substrate surface and an optical device is disposed on the mirror to enable optical coupling in a direction parallel to the substrate surface. (Patent Document 1). Japanese Patent Application Laid-Open No. 2001-42150 discloses that a semi-cylindrical optical waveguide having a semi-cylindrical shape is formed on a substrate, and light is emitted from the substrate side to the curved end surface and reflected in a direction parallel to the substrate surface. Since then, a technique for transmitting light through an optical waveguide has been disclosed (Patent Document 2).
[0005]
[Patent Document 1]
JP 2001-141965 A
[Patent Document 2]
JP 2001-42150 A
[Problems to be solved by the invention]
However, according to the above-described known techniques, any member or part corresponding to a mirror for changing the direction of the emitted light to a direction parallel to the substrate surface is required.
[0006]
In addition, in order to correctly guide the light transmission path, the positional relationship between the optical device and the mirror and the positional relationship between the mirror and the optical transmission path must be adjusted.
[0007]
[Means for Solving the Problems]
SUMMARY OF THE INVENTION An object of the present invention is to provide an optical communication module for optically connecting an optical transmission line and an optical device that extend in a direction different from the direction in which an optical signal of an optical device enters and exits.
[0008]
In order to achieve the above object, an optical communication system according to the present invention includes a plurality of aperture windows formed in a groove formed in a substrate and facing the substrate surface, and each aperture window includes a lens. An optical transmission line and an optical transmission element that emits light along a light emission axis substantially perpendicular to a light emitting point on the surface of the device, and is disposed with the device surface facing the one of the aperture windows. A light receiving element arranged so that light is incident along a light incident axis substantially perpendicular to a light receiving point on the surface of the device, facing the other one of the aperture windows, and facing the device surface; and the light A light reflection film provided around the transmission path, and a plurality of reflection lenses provided on the inner surface side of the light transmission path of the light reflection film, wherein the light emission axis of the light transmission element is an optical of the lens Arranged at a predetermined distance from the central axis of the optical receiver The axis is arranged at a predetermined distance from the optical center axis of the lens, and the plurality of reflection lenses are optical centers of the lenses arranged opposite to the emission axis of the optical transmission element and the optical transmission element. An incident angle of light to the inside of the optical transmission path caused by a deviation from the axis, and an optical axis of the lens arranged opposite to the incident axis of the optical receiving element and the optical receiving element. The lens is disposed at a position corresponding to an optical path corresponding to an emission angle of light toward the lens from the inside of the optical transmission path generated by a deviation, and has a thickness that allows the lens provided in the opening window to fit in the groove. It is characterized by that.
[0009]
According to the above configuration, the light emitted from the optical transmission element substantially vertically reaches the lens provided in the opening window of the transmission path. At this time, since the light emission axis of the light transmitting element and the optical center axis of the lens are deviated, the optical path is bent according to the deviation, and the light becomes oblique light having a directional component parallel to the substrate plane. The oblique light is transmitted while being reflected inside the optical transmission path, reaches the other opening window, and is emitted obliquely. If this light deviates from the optical center axis of the lens provided in the other opening window, it is refracted according to the curvature of the lens and emitted as light substantially perpendicular to the substrate surface. Since the light incident axis of the light receiving element is arranged so as to coincide with the emission direction, light can be incident substantially perpendicularly to the light receiving point. At this time, in the optical transmission path, since it is provided at a position corresponding to the optical path determined by the incident angle and the emission angle of the light into the optical transmission path, light that tends to diffuse in the optical transmission path is collected, It can be efficiently transmitted to the lens provided in the exit side opening window.
[0014]
Here, in the present invention, the “optical device” means a light receiving element that receives an optical signal by a photovoltaic effect, a photoconductive effect, a photoelectron emission effect, a photon drag effect, etc., and converts it into an electric signal, an electroluminescent effect, It means both optical transmission elements that convert electrical signals into optical signals by injection-type light-emitting effect or the like. For example, examples of the light receiving element include a light detector such as a PD and a phototransistor, a photoelectric cell, and an infrared detector. Examples of the optical transmission element include a semiconductor laser and a light emitting diode. These optical devices have a “device surface” and a “light receiving point” or “light emitting point”.
[0015]
The form of the “lens” is not particularly limited, but a lens having a structure that can be easily molded or integrated with an optical device or an optical transmission path is preferable from the viewpoint of manufacturing cost. As the lens, a condensing lens such as a convex lens, a diffusion lens such as a concave lens, or the like can be used. In particular, in order to integrate with an optical device or an optical transmission line, a lens having a flat surface on one side is preferable. A simple shape that is easy to manufacture is preferred. Such a spherical lens has an advantage that the optical center point can be easily grasped, and the amount of refraction changes according to the distance from the optical center point, so that the inclination of the optical path can be easily adjusted.
[0016]
The “optical center axis” is the center point of the lens through which the optical axis passes when the light beam enters the entire effective area of the lens.
[0017]
The amount of “displacement” varies depending on the lens characteristics and type. For example, when a lens having a small curvature and a large optical path change is used, the “deviation” may be smaller than that of a lens having a small curvature. When a convex lens is used, the optical path is refracted in a direction having an optical central axis when viewed from the light emission (incident) axis. Conversely, when a concave lens is used, the optical path is refracted in a direction opposite to the direction in which the optical center axis is located when viewed from the light emission (incident) axis.
[0018]
The structure of the “optical transmission line” is not limited except that an opening window is provided.
[0019]
In addition, it is preferable that the lens is provided on the device surface of the light transmitting element or the light receiving element. According to such a configuration, the lens is integrated with the optical transmission / reception element, which is easy to handle and eliminates the need to adjust the amount of deviation between the optical center axis of the lens and the light incident / exit axis. So easy.
[0031]
The present invention is also an electronic apparatus including the optical communication module including the optical communication module of the present invention or manufactured by the method for manufacturing the optical communication module of the present invention. Since the electronic device includes the optical communication module of the present invention, the manufacturing cost is low, the position adjustment is easy, and the electronic device is excellent for consumer use.
[0032]
Here, the “electronic device” means a general device having a certain function provided with the optical communication module according to the present invention, and its configuration is not particularly limited. For example, a personal computer or a mobile phone provided with the above display device , Video cameras, head-mounted displays, rear-type or front-type projectors, fax machines with display functions, digital camera finders, portable TVs, DSP devices, PDAs, electronic notebooks, electronic bulletin boards, advertising announcement displays, etc. included.
[0033]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
[0034]
First, the principle of the present invention will be described with reference to FIG. FIG. 1A shows a case where a convex lens is used, and FIG. 1B shows a case where a concave lens is used. As shown in FIG. 1A, the optical communication module of the present invention includes an optical device OD and a lens L. The optical device OD enters and exits light along a light incident / exit axis LPA that is substantially perpendicular to the light emitting point LP on the device surface. The lens L is arranged such that the optical center axis LCA passing through the optical center LC is shifted by a predetermined distance Δd from the light incident / exit axis LPA. The optical transmission line OF is optically connected to the optical device OD via the lens L. For example, the optical transmission line OF includes a light incident / exit end surface I / OF on the side surface at the end. The optical transmission line OF normally enters and exits light from the end face side, but depending on the magnitude of the inclination θ of the optical path LP, the incident angle to the end face is too large and is reflected at the end face. In the present embodiment, the incident / exit end surface is provided on the side surface side.
[0035]
For example, since the optical device OD which is an optical transmission element is installed on the substrate surface, the device surface DS is horizontal to the substrate surface. The light incident / exit axis LPA from the light emitting point LP is perpendicular to the substrate surface and has no component in the lateral direction of the substrate. When the light emitted along the light incident / exit axis LPA and incident on the lens L passes through the center LC of the lens L, there should be no change in the optical axis direction due to the convergence of the light flux. However, in the present invention, the lens L is arranged with a deviation of Δd from the light emission axis. Therefore, the light is refracted according to the curvature of the lens L, and the traveling direction is changed, and the light is emitted while being inclined by the angle θ in the direction of the optical central axis LCA of the lens. The tilted light includes a directional component parallel to the substrate surface. Therefore, if this light is incident on the optical transmission line OF from the light incident end face I / OF, light can be transmitted in a direction parallel to the substrate surface while repeating reflection.
[0036]
In addition, the optical communication module using the concave lens as shown in FIG. 1B differs in that the lens Lb is a concave lens, and the lens Lb is arranged on the side opposite to the direction in which the light is to be bent. Different. That is, the optical center axis LCA passing through the optical center LC of the lens Lb is shifted from the light incident / exit axis LPA by Δd on the opposite side to the convex lens. Also in this configuration, the light emitted from the light emitting point LP enters the lens Lb, is refracted in a direction away from the optical center LC by the diffusion action of the concave lens, and is emitted with an inclination of an angle θ.
[0037]
In the case of optical reception, the optical device OD is an optical receiving element and is similar in principle except that the traveling direction of light is different. That is, the light incident on the lenses L and Lb at the angle θ is refracted along the reverse path, and becomes light substantially perpendicular to the substrate surface and enters along the light incident / exit axis LPA.
[0038]
As can be seen from the above principle, the angle θ by which the optical path can be tilted depends on the refraction strength (curvature and material) of the lens and the deviation between the optical central axis LCA and the light incident / exit axis LPA. . Conversely, the lens curvature, material, and amount of deviation may be adjusted so that the tilt angle θ is a desired value.
[0039]
The lens L / Lb may be disposed at any location between the optical device OD and the optical transmission line OF. In view of cost merit, the lens is preferably integrated with the optical device OD or integrated with the optical transmission path. In the following embodiments, each case is shown.
[0040]
(First embodiment)
The first embodiment of the present invention relates to a first optical communication system in which an optical communication module in which an optical device and a lens are integrated is combined with an optical transmission line.
[0041]
FIG. 2 shows a structural diagram of the optical communication module according to the first embodiment. 2A is a plan view of the optical communication module, and FIG. 2B is a sectional view taken along the line BB passing through the light receiving / emitting center point LP and the optical center point LC on the plan view.
[0042]
As shown in FIGS. 2A and 2B, the optical communication module 1a is formed by integrating an optical device body 100 and a lens. The optical device main body 100 is a general optical transmission / reception element such as a surface light emitting diode or a photo detector, and the shape thereof is not limited. A light receiving / emitting point 101 is provided on the device surface 104. In the case of an optical transmission element, light is emitted from the light receiving / emitting point 101 in a direction perpendicular to the device surface 104. In the case of an optical receiving element, light is incident on the light receiving / emitting point 101 from a direction perpendicular to the device surface 104. To do.
[0043]
The lens 102 according to the present invention is formed of a light transmissive material such as glass, quartz, or a transparent curable resin. If the resin material liquid is ejected from the droplet ejection device onto the device surface by a manufacturing method (fifth embodiment: see FIG. 8) described later, the lens 102 is formed of a resin that can be ejected from the droplet ejection device. Is done. The lens 102 has a hemispherical lens shape with a flat bottom surface so as to be integrated with the optical device main body 101. The lens 102 and the device surface 104 of the optical device body 101 may be bonded with a transparent adhesive.
[0044]
As can be seen from FIG. 2B, the optical center point LC of the lens 102 is adjusted so as to be shifted from the light receiving / emitting point 101 of the optical device main body 100 by a distance Δd. That is, the light incident / exit axis LPA extending in the vertical direction from the device surface 104 at the light emitting / receiving point 101 and the optical center axis LCA extending vertically from the optical center point LC of the lens 102 are separated by the distance Δd.
[0045]
Note that the optical communication module may include a control thin film as shown in FIG. 2C if a manufacturing method described later is used. As shown in FIG. 2C, the optical communication module 1 b includes a control thin film 103 between the optical device body 101 and the lens 102. This thin film 103 is patterned in a circular region in accordance with the planned diameter of the lens in order to form the lens 102 with an appropriate diameter. Further, the control thin film 103 is light transmissive, and the affinity with the resin material liquid needs to be adjusted. That is, if the thin film 103 is too compatible with the resin material liquid, the thin film 103 may flow along the surface and the resin material liquid may not remain in the thin film region. On the other hand, if the affinity between the thin film 103 and the resin material liquid is too low, the material liquid may not spread over the entire region where the thin film 103 is formed. The degree of this affinity can be defined by the viscosity of the resin material liquid and the contact angle when the material liquid contacts the thin film.
[0046]
According to the optical communication module 1, since the optical center axis LCA of the lens 102 is separated from the light incident / exit axis LPA by a predetermined distance, the optical path of the incident / exited light is the predetermined angle θ as described in the above principle. It becomes inclined.
[0047]
Referring to FIG. 3, the radius R of the lens L, the deviation Δd between the optical center point LC of the lens and the light receiving / emitting point 101 of the optical device, and the incident / exit end face I / OF of the optical transmission path Explain the relationship. As shown in FIG. 3, the angle formed by the light incident / exit axis LPA and the radial direction from the center LC of the lens L, that is, the incident angle of light with respect to the lens tangent is θ ₁ , The angle between the extension line in the radial direction and the optical axis inclined and emitted from the lens, that is, the angle of light emission from the lens is θ ₀ The incident angle to the incident / exit end face I / OF of the optical transmission line OF is θi.
[0048]
When the width of the light emitting point 101 is D, the deviation Δd when the lens L is a spherical lens is the relationship between the width D of the light emitting point and the lens radius R.
D / 2 <Δd <R−D / 2 (1)
It is preferable to set so that. This is because within this range, almost all of the light emitted from the light emitting point 101 enters the half surface of the lens L.
[0049]
Next, the light exit angle θ from the lens ₀ Is the refractive index of the lens n ₁ If
θ ₀ = Sin ^―1 (N ₁ .DELTA.d / R) (2)
It becomes. The incident angle θ1 of the light with respect to the lens tangent is
θ ₁ = Sin ^―1 (Δd / R) (3)
Therefore, the incident angle θi to the light incident / exit end face I / OF of the optical waveguide OF is
θi = θ ₀ ―Θ ₁ = Θ = sin ^―1 (N ₁ ・ Δ / R)
-Sin ^―1 (Δd / R) (4)
It is expressed. Since reflection on the surface of the optical waveguide OF is the least reflected when incident so as to have a Brewster angle, Δd and R are preferably set so that θi is close to the Brewster angle of the optical waveguide OF. .
[0050]
The Brewster angle is an angle at which the reflection coefficient is 0 and the transmission coefficient is 1 at a certain angle, and is when the electric field vector of the incident light coincides with the wave number direction of the refracted light. This is a case where the vertical electric field component disappears. It is called the Brewster angle in the name of the discoverer of this angle (Brewster).
Next, a first optical communication system using the optical communication module 1 will be described. 4A is a cross-sectional view taken along the optical axis in the first optical communication system, and FIG. 4B is a cross-sectional view taken along the BB cut surface in FIG. 4A of the optical axis. Show.
[0051]
As shown in FIG. 4A, the optical communication system includes an optical transmission module 1T, an optical transmission line 2a, and an optical reception module 1R. The optical transmission line 2 a is accommodated in the groove 301 formed in the substrate 300. As shown in FIG. 4B, the optical transmission line 2a has a rectangular cross section. However, the cross-sectional shape of the optical transmission line is not limited to a rectangle, and may be another polygon or a circle. The optical transmission line 2a includes a main body 200 and a reflective film 203 formed around the main body 200. The reflection film 203 may be formed of a film that can totally reflect light, and is a metal thin film such as aluminum. The reflective film 203 is not necessarily formed, and may be formed by spraying a light reflecting material around the main body 200. Opening windows 201 and 202 for emitting light are provided on the side surface of the end of the optical transmission line 2a, and the reflection film 203 is not formed. Regardless of the shape of the cross section of the main body 200, the region corresponding to the opening windows 201 and 202 preferably forms a flat surface. This is to secure a certain area for light entering / exiting light from / to the optical communication module under the same conditions.
[0052]
In addition, you may provide three or more opening windows not only in two. By increasing the intensity of light to be transmitted, it is possible to receive a plurality of lights by one light transmission.
[0053]
The optical transmission module 1T has a structure as described in FIGS. Specifically, an optical transmission element such as a surface light emitting diode that converts an electrical signal into an optical signal is used as the optical device 100, and the optical device and the lens 102 are integrally formed. For this reason, light emitted vertically from the device surface 104 of the optical transmission element is emitted obliquely. The optical transmission module 1T is positioned so that the emitted oblique light is substantially incident on the opening window 201 of the optical transmission path 2a.
[0054]
The same applies to the optical receiving module 1R, which has the structure described with reference to FIGS. Specifically, an optical receiving element that converts an optical signal into an electric signal, such as a photodetector, is the optical device 100, and the optical device and the lens 102 are integrally formed. Light incident obliquely on a predetermined portion of the lens is incident perpendicularly to the device surface 104 including the light receiving point of the light receiving element. The optical receiving module 1R is positioned so that oblique light emitted from the opening window 202 of the optical transmission path 2a can be refracted by the lens 102 and can enter the light receiving point 101 substantially perpendicularly.
[0055]
In the above configuration, light emitted obliquely from the optical transmission module 1T enters the main body 200 from any location of the opening window 201 of the optical transmission path 2a. The incident light is repeatedly totally reflected by the reflection film 203 according to the incident angle and transmitted in a direction parallel to the substrate surface. And it inject | emits from the opening window 202, and reaches | attains the lens 102 of the optical receiving module 1R. This light is refracted by the lens 102 and enters the light receiving point 101 as light from a direction perpendicular to the device surface.
[0056]
According to the first embodiment, light from the optical transmission module 1T is transmitted along the substrate surface without using a mirror or the like, and again as light in a direction perpendicular to the substrate surface without using a mirror or the like. The light can be incident on the light receiving element. For this reason, use of a mirror member, a position, angle adjustment, etc. are unnecessary.
[0057]
Further, according to the first embodiment, the light from the optical transmission module 1T only needs to be incident on the aperture window, so that alignment is easy. In addition, special members such as mirrors are not required for both input and output.
[0058]
Further, according to the first embodiment, if an open window is secured as the optical transmission line 2a, a normal optical fiber can be used and is easy to manufacture.
[0059]
According to the first embodiment, since the optical transmission line is surrounded by the reflection film that performs total reflection, light loss can be suppressed.
[0060]
According to the first embodiment, since the projection of the lens portion of the optical communication module is placed in the groove, it is easy to mount the optical communication system.
[0061]
(Second Embodiment)
The second embodiment of the present invention is a second optical communication system in which an optical transmission module in which an optical device and a lens are integrated is combined with an optical transmission line having a form different from that of the first embodiment. About. The specific structure of the optical communication module is the same as that in the first embodiment.
[0062]
A second optical communication system according to the second embodiment will be described. FIG. 5A is a cross-sectional view taken along the optical axis in the second optical communication system, and FIG. 5B is a side view of the optical communication system viewed from the optical transmission module side.
[0063]
As shown in FIGS. 5A and 5B, the optical communication system includes an optical transmission module 1T, an optical transmission path 2b, and an optical reception module 1R. Unlike the first embodiment, the optical transmission line 2b of the present embodiment is provided so as to stand on the substrate 300. The entire optical transmission line 2b is formed of a light transmissive material, for example, a curable resin, and an incident end face 211 for allowing light from the optical transmission module 1T to enter the optical transmission path 2b and the optical reception module 1R. And an emission end face 212 for emitting light to the. The optical transmission line 2b and the optical transmission module 1T are positioned so that oblique emission light from the optical transmission module 1T enters the incident end surface 211. The optical transmission line 2b and the optical receiving module 1R are positioned so that oblique emission light from the emission end face 212 enters the optical reception module 1R. In FIG. 5, the main body 210 is formed in a bowl shape, that is, in a cross-sectional shape close to a semi-cylindrical shape, but is not limited thereto, and may be formed in a polygonal shape such as a rectangle. Regardless of the shape of the cross section of the main body 210, it is preferable that the regions corresponding to the incident end face 211 and the exit end face 212 form a plane. This is to secure a certain area for light entering / exiting light from / to the optical communication module under the same conditions.
[0064]
The optical transmission module 1T is positioned so that light emitted from the light emitting point 101 and refracted in an oblique direction enters the incident end surface 211 of the optical transmission line 2b. With respect to the optical receiving module 1R, oblique light emitted from the emission end face 212 of the optical transmission line 2b is refracted by the lens 102 and can enter the device surface 104 including the light receiving point 101 of the optical receiving element substantially perpendicularly. It is positioned.
[0065]
In addition, about the optical transmission line 2b, the utilization efficiency of light can be raised by providing a reflection film in the circumference | surroundings. In this case, however, the incident end face 211 and the exit end face 212 are not covered.
[0066]
In the above configuration, light emitted obliquely from the optical transmission module 1T enters the main body 210 from any location on the incident end face 211 of the optical transmission path 2b. The incident light is transmitted in a direction parallel to the substrate surface by repeating total reflection on the wall surface according to the incident angle. Then, the light is emitted from the emission end face 212 and reaches the lens 102 of the optical reception module 1R. This light is refracted by the lens 102 and enters the light receiving point 101 as light from a direction perpendicular to the device surface 104.
[0067]
According to the second embodiment, light from the optical transmission module 1T is transmitted along the substrate surface without using a mirror or the like, and again as light in a direction perpendicular to the substrate surface without using a mirror or the like. The light can be incident on the light receiving element. For this reason, use of a mirror member, a position, angle adjustment, etc. are unnecessary.
[0068]
In addition, according to the second embodiment, the light from the optical transmission module 1T only needs to be incident on the opening end face, and thus alignment is easy. In addition, special members such as mirrors are not required for both input and output.
[0069]
Further, according to the second embodiment, since the projection of the lens portion of the optical communication module can be directed upward of the substrate, it is easy to mount the optical communication system.
[0070]
(Third embodiment)
The third embodiment of the present invention relates to a third optical communication system using an optical transmission line in which lenses are integrated.
[0071]
The third optical communication system according to the third embodiment has a configuration similar to that of the first embodiment, but instead of having a lens in the optical communication module, a lens is provided at the opening window of the optical transmission path. It differs in that it is provided.
[0072]
A third optical communication system according to the third embodiment will be described. 6A is a cross-sectional view taken along the optical axis in the third optical communication system, and FIG. 6B is a cross-sectional view taken along the BB cut surface of FIG. 6A of the optical axis. Show.
[0073]
As shown in FIG. 6A, the optical communication system includes an optical transmission element 4T, an optical transmission line 2c, and an optical reception element 4R. The optical transmission line 2 c is accommodated in the groove 301 formed in the substrate 300. As shown in FIG. 6B, the optical transmission line 2c has a rectangular cross section. However, the cross-sectional shape of the optical transmission line is not limited to a rectangle, and may be another polygon or a circle. The optical transmission line 2c includes a main body 220 and a reflective film 223 formed around the main body 220. The reflection film 223 may be formed of a film that can totally reflect light, and is a metal thin film such as aluminum. The reflective film 223 does not need to be formed, and may be formed by spraying a light reflecting material around the main body 220. In particular, in the present embodiment, the reflective lens 224 is provided along the optical transmission path in order to efficiently collect light. It is the same as that of the said 1st Embodiment that the opening windows 221 and 222 are provided in the edge part side surface of the optical transmission line 2c. However, the opening windows 221 and 222 differ in that a lens 225 similar to that provided in the optical communication module 1a is integrally formed.
[0074]
The optical transmission element 4T is an ordinary optical device for optical transmission, for example, a surface emitting diode itself. Similarly, the optical receiving element 4R is a normal optical receiving optical device, for example, a photo detector. For this optical transmission element 4T, the light emitted perpendicularly from the light emitting point 101 on the device surface 104 is shifted in a direction parallel to the substrate plane by a predetermined distance from the predetermined position of the lens 225, that is, the optical center axis of the lens. Positioned to enter the position.
[0075]
The optical receiving element 4R is also an ordinary optical device for receiving light, for example, a photodetector. The light receiving element 4R is positioned so that light that reaches the opening window 222 of the light transmission path 2c, is refracted by the lens 225, and is emitted perpendicularly to the substrate plane enters the light receiving point 101.
[0076]
In the above configuration, the light emitted vertically from the optical transmission element 4T is incident on the lens 225 of the opening window 221 of the optical transmission path 2c at a position shifted by a predetermined distance from the optical center position of the lens. The incident light is refracted by the lens 225 and becomes oblique light having an incident angle θ. This light is transmitted in a direction parallel to the substrate surface by repeating total reflection at the reflection film 203 according to the incident angle. Then, the light is again emitted from the opening window 202 in the direction perpendicular to the plane of the substrate by the refractive action of the lens 225, and reaches the light receiving point 101 of the light receiving element 4R.
[0077]
According to the third embodiment, the light from the optical transmission element 4T is transmitted along the substrate surface without using a mirror or the like, and as light in a direction perpendicular to the substrate surface again without using a mirror or the like. The light can be incident on the light receiving element 4R. For this reason, use of a mirror member, a position, angle adjustment, etc. are unnecessary.
[0078]
According to the third embodiment, since the optical transmission line is surrounded by the reflection film that performs total reflection, light loss can be suppressed.
[0079]
According to the third embodiment, since the projection of the lens portion of the optical communication module is placed in the groove, it is easy to mount the optical communication system.
[0080]
According to the third embodiment, a normal optical device can be used for the optical transmission element 4T and the optical reception element 4R.
[0081]
(Fourth embodiment)
The fourth embodiment of the present invention is a fourth optical communication in which an optical transmission path using an optical transmission path with an integrated lens is combined with an optical transmission path having a form different from that of the third embodiment. About the system.
[0082]
A fourth optical communication system in the fourth embodiment will be described. FIG. 7A shows a cross-sectional view taken along the optical axis in the fourth optical communication system, and FIG. 7B shows a side view of the optical communication system viewed from the optical transmission module side.
[0083]
As shown in FIGS. 7A and 7B, the optical communication system includes an optical transmission element 4T, an optical transmission path 2d, and an optical reception element 4R. Unlike the third embodiment, the optical transmission line 2d of the present embodiment is provided to stand on the substrate 300. The entire optical transmission line 2d is formed of a light-transmitting material, for example, a curable resin, and an incident end face 231 for allowing light from the optical transmission element 4T to enter the optical transmission line 2d and the optical reception element 4R. And an emission end face 232 for emitting light to the. Further, a lens 233 is provided on the incident end face 31, and a lens 234 is provided on the exit end face 232.
[0084]
The optical transmission element 4T is an ordinary optical device for optical transmission, for example, a surface emitting diode itself. Similarly, the optical receiving element 4R is a normal optical receiving optical device, for example, a photo detector. With respect to this optical transmission element 4T, the light emitted vertically from the light emitting point 101 on the device surface 104 is shifted in a direction parallel to the substrate plane by a predetermined distance from the predetermined position of the lens 233, that is, the optical center axis of the lens. It is positioned so as to be incident on the position.
[0085]
The optical receiving element 4R is also an ordinary optical device for receiving light, for example, a photodetector. The light receiving element 4R is positioned so that light that reaches the emission end 232 of the optical transmission path 2d, is refracted by the lens 234, and is emitted perpendicularly to the plane of the substrate enters the light receiving point 101 of the light receiving element 4R. The
[0086]
In FIG. 5, the main body 230 is formed into a bowl shape, that is, a cross-sectional shape close to a semi-cylindrical shape, but is not limited thereto, and may be formed in a polygonal shape such as a rectangle.
[0087]
In the above configuration, the light emitted vertically from the optical transmission element 4T is incident on the lens 233 on the incident end face 231 of the optical transmission line 2d at a position shifted by a predetermined distance from the optical center position of the lens. The incident light is refracted by the lens 233 and becomes oblique light having an incident angle θ. This light is repeatedly reflected on the wall surface of the main body 230 according to the incident angle and transmitted in a direction parallel to the substrate surface. Then, the light reaches the opposite emission end face 232 and is emitted again in a direction perpendicular to the substrate plane by the refraction of the lens 234, and reaches the light receiving point 101 of the light receiving element 4R.
[0088]
According to the fourth embodiment, the light from the optical transmission element 4T is transmitted along the substrate surface without using a mirror, and the light is again perpendicular to the substrate surface without using a mirror. The light can be incident on the light receiving element. For this reason, use of a mirror member, a position, angle adjustment, etc. are unnecessary.
[0089]
According to the fourth embodiment, since the projection of the lens portion is provided in the optical transmission path, it is easy to mount the optical communication system.
[0090]
According to the fourth embodiment, a normal optical device can be used for the optical transmission element 4T and the optical reception element 4R.
[0091]
(Fifth embodiment)
The fifth embodiment of the present invention relates to a specific example of a method for manufacturing an optical communication module according to the present invention. The manufacturing method will be described with reference to the manufacturing process sectional view of FIG.
[0092]
First, the control thin film 103 is formed on the device surface of the optical device 100 (ST1). The control thin film 103 is formed of a material that is light transmissive and has an affinity for the resin material liquid. For example, it can be formed by applying a predetermined resin material. Next, the control thin film 103 is patterned into the shape of the planned formation region of the lens 102 (ST2). At this time, the distance between the target light incident / exit point 101 and the optical center LC is set based on the principle of the present invention.
[0093]
Next, an appropriate amount of the light transmissive resin material liquid 11 is discharged from the liquid discharge apparatus 10 having a structure equivalent to that of the piezo jet recording head onto the surface of the control thin film 103 (ST3). This material liquid 11 is adjusted to a viscosity suitable for droplet discharge by dissolving a light-transmitting resin in a solvent. The discharge amount is set so as not to overflow from the control thin film 103.
[0094]
Next, the solvent contained in the discharged resin material liquid 11 is heated and dried (ST4). When the solvent evaporates, the resin material liquid 11 is solidified, but its volume is considerably reduced, and a sufficient surface curvature may not be obtained. In such a case, the discharging step (ST3) of the resin material liquid 11 and the heat drying step (ST4) are repeated again, and the light transmissive resin is laminated until the desired curvature is obtained.
[0095]
Through the above steps, the lens 102 of the present invention is formed on the control thin film 103. The deviation Δd between the radius R of the lens and the optical center LC and the light receiving / emitting point LP is set according to the relationship described above. The optical characteristics of the lens are determined by the viscosity of the lens material, the discharge amount of the lens material, and the like.
[0096]
Note that the lens 102 may be formed by ejecting the material liquid around the optical center point LC while controlling the position without forming the control thin film 103 in the above process.
[0097]
The above example is an example using a control thin film that adjusts the affinity with the resin material liquid. However, when this is not used, for example, forming a depression (bank) at a predetermined location on the device surface 104 is not possible. preferable. An ultraviolet curable resin or the like is discharged into the recess until it becomes a lens shape by an ink jet technique, and is cured by being irradiated with ultraviolet rays. The optical characteristics of the lens are determined by the shape of the bump, the viscosity of the lens material, the discharge amount of the lens material, and the like.
As described above, according to the fifth embodiment, the optical communication module of the present invention can be easily formed by using the droplet discharge method.
[0098]
(Sixth embodiment)
The sixth embodiment of the present invention relates to an electronic apparatus provided with the optical communication module of the present invention, particularly a personal computer.
[0099]
FIG. 9 is a perspective view showing the configuration of the personal computer 1000 in this embodiment. In FIG. 9, the personal computer 1000 includes a display panel 1001 and a main body 1004 provided with a keyboard 1002. An optical communication module manufactured by the method for manufacturing an optical communication module of the present invention is used for communication between the built-in substrates of the main body 1004 of the computer display device 1000 and between the main body 1004 and the display panel 1001.
[0100]
The optical communication module according to the present invention is not limited to the above example, and can be applied to the manufacture of any electronic device that uses high-speed communication called optical communication.
[0101]
(Other deformation possibilities)
In addition, this invention is not limited to each embodiment mentioned above, It can change variously within the range of the summary as described in the claim of this invention.
[0102]
For example, in the present invention, an example in which the lens is integrated on the optical device side (first and second embodiments), and an example in which the lens is integrated on the optical transmission line side (third and fourth embodiments). However, the present invention is not limited to this.
[0103]
That is, the optical communication system may be configured such that the lens and the optical device are integrated on the optical transmission side, and the lens and the optical transmission path are integrated on the optical reception side. Conversely, the optical communication system may be configured such that the lens and the optical transmission path are integrated on the optical transmission side, and the lens and the optical device are integrated on the optical reception side.
[0104]
Further, the lens does not have to be integrated, and may be arranged between the optical device and the optical transmission path to constitute an optical communication system.
[0105]
In the above embodiment, an independent optical communication module is exemplified, but a module array may be used. For example, a lens array in which optical center points are arranged at the same pitch is aligned on an optical device array in which light incident / exit points are provided at a predetermined pitch. Since the pitch between the two is the same, the positional deviation between the light incident / exit point and the optical center point of each optical device is equal in any pair. Therefore, by configuring an optical communication module array in which such an optical device array and a lens array are combined, the inclination of the incident / exited light can be adjusted uniformly throughout the array.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating the principle of an optical communication module according to the present invention.
FIG. 2 is a configuration diagram of an optical communication module according to the embodiment.
FIG. 3 is a relationship diagram of each element in the optical module of the present invention.
FIGS. 4A and 4B are configurations of the optical communication system according to the first embodiment, in which FIG. 4A is a side sectional view, and FIG.
FIGS. 5A and 5B are configurations of an optical communication system according to a second embodiment, in which FIG. 5A is a side view and FIG. 5B is a front view as viewed from the optical transmission element side of FIG.
6A and 6B show a configuration of an optical communication system according to a third embodiment, in which FIG. 6A is a side sectional view, and FIG. 6B is a sectional view taken along line BB in FIG.
7A and 7B show a configuration of an optical communication system according to a fourth embodiment, in which FIG. 7A is a side view, and FIG. 7B is a front view as viewed from the optical transmission element side of FIG.
FIG. 8 is a manufacturing process cross-sectional view of an optical communication module according to a fifth embodiment.
FIG. 9 is an example of an electronic apparatus according to a sixth embodiment of the present invention, and illustrates a portable personal computer.
[Explanation of symbols]
OD: Optical device (optical transmission element, optical reception element), OF: Optical fiber (optical transmission path), L: Lens, LPA: Light incident / exit axis, LCA: Optical central axis, LP: Optical path, Δd: Deviation amount DESCRIPTION OF SYMBOLS 1T, 4T ... Optical transmitting element, 1R, 4R ... Optical receiving element, 2a-2d ... Optical transmission line, 100 ... Optical device main body, 101 ... Light emitting / receiving point, 102 ... Condensing lens, 103 ... Affinity thin film, 104 ... Device surface, 200, 210, 220, 230 ... Optical transmission line main body, 201, 211, 221, 231 ... Incident side opening window, 202, 212, 222, 232 ... Emission side opening window, 203, 223 ... Reflecting film, 224 ... Reflective lens, 233, 234, 225 ... Lens, 300 ... Substrate, 301 ... Groove

Claims (2)

A plurality of aperture windows formed in a groove formed in the substrate and facing the substrate surface, each of the aperture windows having an optical transmission path;
A light transmitting element that emits light along a light emission axis substantially perpendicular to a light emitting point on the device surface and faces the device surface facing one of the aperture windows, and a light receiving point on the device surface A light receiving element that is arranged with a light incident along a light incident axis substantially perpendicular to the aperture window, facing the other one of the aperture windows and facing the device surface;
A light reflecting film provided around the light transmission path;
A plurality of reflection lenses provided on the inner surface side of the light transmission path of the light reflection film,
The light emission axis of the light transmitting element is disposed at a predetermined distance from the optical center axis of the lens,
The light incident axis of the light receiving element is disposed at a predetermined distance from the optical center axis of the lens,
The plurality of reflection lenses are configured such that light is incident on the inside of the optical transmission path caused by a deviation between the emission axis of the optical transmission element and the optical central axis of the lens disposed to face the optical transmission element. The light from the inside of the optical transmission path to the lens, which is generated due to an angle and a deviation between the incident axis of the light receiving element and the optical center axis of the lens arranged to face the light receiving element. It is arranged at a position corresponding to the optical path according to the emission angle,
An optical communication system , wherein the lens provided in the opening window has a thickness that fits in the groove .   An electronic device comprising the optical communication system according to claim 1.

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