JPWO2016051836A1 - Optical component, optical module, and method of manufacturing optical component - Google Patents

Abstract

The optical component according to the present invention includes a substrate (1), a prism (2) disposed in contact with the substrate upper surface (1a), a lens-integrated prism (4) in which the lens and the prism are integrated, and light transmission. The prism (2) and the lens integrated prism (4) are bonded via the bonding member (3), and the prism lower surface (4d) of the lens integrated prism (4) ), The prism lower surface (2c) and the prism upper surface (2b) of the prism (2) are parallel to the substrate (1), the mirror surface (4a) of the lens integrated prism (4) and the mirror of the prism (2) The surfaces (2a) are each non-parallel to the substrate (1) and non-parallel to the optical axis of the lens of the lens-integrated prism (4), and the optical axis of the lens of the lens-integrated prism (4) is the substrate ( Parallel to 1).

Description

  The present invention relates to an optical component, an optical module, and an optical component manufacturing method used for optical communication and the like.

  A light emitting / receiving element such as a semiconductor LD (Laser Diode) or PD (Photo Diode) and optical components such as a lens, a mirror, a filter, and a planar waveguide chip are hermetically sealed having an optical input / output port such as a fiber receptacle. An optical module housed in one package is used in communication equipment such as an optical transceiver. In an optical module, in order to achieve high-efficiency connection between the light emitting / receiving element and the fiber inserted in the optical input / output port, the optical components inside the package are arranged with high precision, and the light emitting / receiving element and the planar waveguide chip are guided. It is necessary to align the optical path center of the optical system with the optical axes of the waveguide element and the fiber. However, there are variations in the optical axis height of the light emitting / receiving element, the planar waveguide chip, and the fiber. Further, misalignment occurs when these are die-bonded. In addition, the spatial multiplexer / demultiplexer also causes an angle deviation of the incident / exit optical axis. In order to correct these deviations, the optical path center angle of the optical system is generally corrected by adjusting the position and angle of the optical components arranged in the optical system, such as adjusting the position of the lens and the angle of the mirror and the prism. Done.

  In recent years, miniaturization and integration of optical modules have progressed. For example, Patent Document 1 discloses an integrated optical module that is an optical module in which a plurality of LD elements, a plurality of lenses, and a multiplexer including a plurality of filters are integrated. In an integrated optical module, in general, light receiving and emitting elements and optical components are two-dimensionally arranged on the same mounting board plane or within a limited height range, and the optical path center is in a direction horizontal to the mounting board. There are many. This is because it is easy to place various parts, and it is easy to form a complicated optical system such as a multiplexer / demultiplexer, and when many parts are stacked, the height tolerance of each part accumulates and it is easy to cause an optical axis shift. It is.

  Here, in the arrangement of the optical components, the adjustment of the position in the direction perpendicular to the mounting substrate plane and the elevation angle is an issue. Specifically, when the optical axis direction in the horizontal plane horizontal to the mounting board is the Z axis, the direction perpendicular to the optical axis in the horizontal plane is the X axis, and the direction perpendicular to the plane of the mounting board is the Y axis, X-axis position and angle adjustment is possible by horizontal movement in the XZ plane and rotation around the Y-axis, whereas Y-axis position adjustment and angle adjustment around the X and Z axes. However, it is necessary to appropriately control the thickness, that is, the height and distribution of the joining member while ensuring a sufficient joining member thickness. In general, as the bonding member, a heat-meltable bonding member such as solder, or an acrylic or epoxy resin bonding member that is cured by irradiation with heat or UV (Ultra Violet) light is used. These joining members have several percent shrinkage when solidified or cured. When the thickness of the joining member is large, a vertical position shift, a change in inclination, and a horizontal position shift due to nonuniform residual stress occur due to shrinkage of the bonding agent member. When the thickness of the joining member is large, the joining member of the adjacent optical component flows out and interferes before curing, and the optical component cannot be fixed at a desired position with high accuracy. In order to suppress these, it is necessary to reduce the thickness of the joining member, but in this case, the necessary vertical range and angle adjustment range cannot be ensured.

  Patent Document 2 and Patent Document 3 are examples of a method for correcting the position and angle of the optical component in the vertical direction and correcting the optical path center angle of the optical system. In Patent Document 2, the optical module is configured so that the center line of curvature of the cylindrical lens is tilted around the optical axis. In Patent Document 2, the height of the lens surface center can be changed by moving the cylindrical lens in the horizontal direction, the difference between the center line of the lens surface and the height of the incident optical path center is changed, and the height of the optical path center is changed. A method for changing the depression angle is disclosed. Patent Document 3 discloses a method of forming a gonio mechanism on a reflecting plate in order to enable angle adjustment around an arbitrary axis in the reflecting plate.

JP 2014-102498 A JP2012-083401A JP 2013-205629 A

  However, in the method described in Patent Document 2, the light beam is distorted in the inclination direction of the lens surface center line, and the coupling efficiency is lowered even if the optical axes are aligned. Patent Document 2 discloses that the tilt of the lens center line is suppressed to at least 30 degrees or less in order to prevent a decrease in coupling efficiency. In this case, in order to obtain a desired optical axis correction angle, a large horizontal direction is disclosed. Movement is necessary, and interference with adjacent optical components occurs. Further, a separate optical component is required to correct the optical path center angle in the optical axis horizontal plane.

  Further, in the method described in Patent Document 3, when a complicated optical system is assembled, it is necessary to arrange a large number of reflecting plates and adjust each of them, and it is necessary to align the center of rotation according to the position of each reflecting plate. . In order to realize this, it is necessary to introduce a complicated mechanism in the head that temporarily holds and arranges the reflecting plate.

  The present invention has been made in view of the above, and an object thereof is to obtain an optical component capable of appropriately adjusting the vertical position and the elevation angle of the optical path.

  In order to solve the above-described problems and achieve the object, the present invention includes a substrate, a prism disposed in contact with the upper surface of the substrate, a lens-integrated prism in which the lens and the prism are integrated, and light transmission. A lower surface that is a surface of the lens-integrated prism on the side of the prism, and an upper surface of the substrate of the prism. A lower surface that is in contact with the upper surface of the substrate and the upper surface of the prism are parallel to the upper surface of the substrate, and the lens-integrated prism and the mirror surface of the prism are each non-parallel to the upper surface of the substrate and are integrated with the lens. The lens integrated prism is non-parallel to the optical axis of the lens of the prism, and the optical path center of the light incident on the prism is parallel to the upper surface of the substrate. Wherein the optical axis of the lens is parallel to the upper surface of the substrate.

  The optical component according to the present invention has an effect that the vertical position of the optical path and the elevation angle can be appropriately adjusted.

Sectional drawing of the optical component concerning Embodiment 1 The figure which shows an example of the manufacturing method of the optical component concerning Embodiment 1. FIG. The figure which shows an example of the manufacturing method of the optical component concerning Embodiment 1. FIG. The figure which shows an example of the locus | trajectory of the optical path center at the time of entering light from -Z direction in the process of the optical component concerning Embodiment 1. The figure which shows sectional drawing of the optical component concerning Embodiment 2. FIG. Sectional drawing of the optical component concerning Embodiment 3 Sectional drawing of the optical component concerning Embodiment 4 Top view of optical component of Embodiment 4 having a plurality of LDs and submounts Sectional drawing of the optical component concerning Embodiment 5 Sectional drawing of the optical component concerning Embodiment 6

  Embodiments of an optical component, an optical module, and an optical component manufacturing method according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments. In the drawings shown below, the scale of each member may be different from the actual for easy understanding, and the same applies to the drawings.

Embodiment 1 FIG.
1 is a cross-sectional view of an optical component according to Embodiment 1 of the present invention. The optical component of the present embodiment is mounted on, for example, an optical module in an optical communication device. As shown in FIG. 1, the optical component of the present embodiment includes a substrate 1 formed of a material having high surface accuracy such as ceramics or glass, a prism 2 in contact with the first surface of the substrate 1, and the prism 2 as a substrate. 1 is provided with a joining member 3 formed in contact with a surface opposite to the surface in contact with 1, and a lens integrated prism 4 joined to the prism 2 through the joining member 3. FIG. 1 shows an example in which a convex lens surface is formed on the lens integrated prism 4.

  As shown in FIG. 1, the surface of the substrate 1 that contacts the prism 2 is defined as a substrate upper surface 1a. Further, when the mirror surface of the prism 2 is a mirror surface 2a, the surface of the prism 2 in contact with the substrate 1 is a prism lower surface 2c, and when the prism lower surface 2c is the back surface of the prism 2, the surface corresponding to the front side of the prism 2 is the prism upper surface 2b. To do. The mirror surface of the lens integrated prism 4 is a mirror surface 4a, the surface of the lens formed on the lens integrated prism 4 is a lens surface 4b, and the surface on which the lens of the lens integrated prism 4 is formed is the lens main surface. The surface of the lens-integrated prism 4 that is in contact with the bonding member 3 is referred to as a prism lower surface 4d. The direction from the substrate 1 to the prism 2 is the upward direction, the direction from the prism 2 to the substrate 1 is the downward direction, the upper surface of each member is called the upper surface, and the lower surface is called the lower surface.

  The bonding member 3 is a transparent bonding member that transmits light and is preferably a transparent resin bonding agent that is cured by heat or UV irradiation. Thermosetting bonding agents that are cured by heat have high bonding strength and are reliable. An ultraviolet curable bonding agent that is cured by UV irradiation is excellent in convenience, such as when each optical element can be individually arranged and fixed when bonding a plurality of optical elements. Some UV curable adhesives can be further heated to increase the bonding strength after curing by UV irradiation. The use of such adhesives makes the UV curable adhesive convenient and reliable thermosetting adhesives. It is more preferable because it has both sex.

  The prism lower surface 4 d of the lens integrated prism 4 is bonded to the prism upper surface 2 b of the prism 2 via the bonding member 3. The prism 2 and the lens-integrated prism 4 are preferably made of the same material or a material having a similar linear expansion coefficient. When the same material or a material having a similar linear expansion coefficient is used, when heating is performed in the curing that is bonding, the prism 2 and the lens integrated prism 4 are peeled off by heating, and the prism 2 and the lens integrated prism are heated. The positional deviation before and after joining with 4 can be suppressed.

  In general, the material of the prism 2 and the lens-integrated prism 4 is glass, plastic, or resin, but it is preferable to use glass having a small linear expansion coefficient. By using glass with a small linear expansion coefficient, it is possible to suppress the optical axis shift with respect to temperature fluctuations during operation of the optical module on which the present embodiment is mounted.

  The substrate upper surface 1a, the prism upper surface 2b, the prism lower surface 2c, and the prism lower surface 4d are preferably parallel, and the lens main surface 4c on which the lens surface 4b is formed is preferably perpendicular to the substrate upper surface 1a. The mirror surface 2a of the prism 2 and the mirror surface 4a of the lens-integrated prism 4 are each non-parallel to the substrate upper surface 1a. The mirror surface 2 a of the prism 2 and the mirror surface 4 a of the lens integrated prism 4 are each non-parallel to the optical axis of the lens of the lens integrated prism 4. Note that the mirror surface 2a of the prism 2 and the mirror surface 4a of the lens-integrated prism 4 preferably form an angle of 45 degrees with the substrate upper surface 1a.

  The direction in which light enters the optical component is taken as the Z axis, the direction perpendicular to the Z axis in the plane of the substrate upper surface 1a is taken as the X axis, and the direction perpendicular to the substrate upper surface 1a is taken as the Y axis. Here, it is assumed that light is incident from the −Z direction parallel to the substrate upper surface 1a.

  Next, the manufacturing method of the optical component concerning this Embodiment is demonstrated. 2 and 3 are diagrams showing a method of manufacturing an optical component according to the present embodiment. First, as shown in FIG. 2, in step 1, the prism 2 is disposed so that the prism lower surface 2c is in contact with the substrate upper surface 1a of the substrate 1, and the bonding member 3 is disposed on the prism upper surface 2b. Next, as step 2, as shown in FIG. 3, before the bonding member 3 is cured, the lens integrated prism 4 is disposed in contact with the bonding member 3, and the lens integrated prism 4 is light-transmitted as described later. The elevation angle of the light emitted from the optical component is adjusted by moving the component in the optical axis direction of the incident light. Thereafter, as Step 3, the joining member 3 is cured.

  Next, a method for adjusting the height and elevation angle of the optical system according to the present embodiment in Step 2 described above will be described. In this embodiment, the prism 2 is fixed to the substrate 1 and the lens-integrated prism 4 is moved in parallel with the center of the optical path before the bonding member 3 is cured, so that the height and height of the light emitted from the optical component are increased. Adjust the depression angle.

  FIG. 4 is a diagram illustrating an example of the locus of the optical path center when light is incident from the −Z direction. As shown in FIG. 4, the optical path center at the time of incidence on the optical component, that is, the optical path center of the light incident on the prism 2 is defined as an optical path center 5a. The optical path center 5a is parallel to the substrate 1 (substrate upper surface 1a). In addition, illustration of the board | substrate 1 is abbreviate | omitted in FIG. The surface on the −Z side of the prism 2 is defined as a side surface 2d. When light enters the prism 2, it is generally refracted. The optical path center of the light after entering the prism 2 is defined as an optical path center 5b. And light is reflected by the mirror surface 2a. The optical path center of the light reflected by the mirror surface 2a is defined as an optical path center 5c. Further, the light passes through the bonding member 3 and enters the lens integrated prism 4. It is assumed that the lens-integrated prism 4 is disposed at a position where the light passing through the optical path center 5c can be reflected by the mirror surface 4a in the ZX plane. The optical path center of the light incident on the lens integrated prism 4 is defined as an optical path center 5d. The light incident on the lens integrated prism 4 is reflected by the mirror surface 4a. The optical path center of the light reflected by the mirror surface 4a is defined as an optical path center 5e. The light reflected by the mirror surface 4a passes through the lens surface 4b. The optical path center of the light that has passed through the lens surface 4b is defined as an optical path center 5f. The optical axis of the lens of the lens integrated prism 4 is parallel to the substrate 1 (substrate upper surface 1a).

  When the radius of curvature of the lens surface 4b is infinite, that is, when the lens surface 4b is in a flat limit, the mirror surface 2a of the prism 2 and the mirror surface 4a of the lens-integrated prism 4 are parallel and the side surface 2d of the prism 2 And the lens main surface 4c of the lens-integrated prism 4 are parallel to each other, the optical path center 5a before passing through the optical component and the optical path center 5f after passing through become parallel. Here, it is assumed that the prism 2 is fixed and the lens integrated prism 4 is moved in parallel with the optical path center 5a to adjust the horizontal relative position between the fixed prism 2 and the lens integrated prism 4. In this case, the vertical position of the optical path center 5e, that is, the position in the Y-axis direction changes according to the position of the lens integrated prism 4. If the position in the Z-axis direction of the lens integrated prism 4 in the example of FIG. 4 is the first position, the optical path center 5d is the mirror surface 4a at the second position where the lens integrated prism 4 is moved in the −Z direction. The position where the lens is integrated is higher than when the lens-integrated prism 4 is positioned at the first position.

  Here, when the radius of curvature of the lens surface 4b is finite, if the height of the optical path center 5e is changed, the incident angle is shifted from the center of the lens surface 4b, so that the emission angle of the optical path center 5f changes. Thus, the elevation angle of the optical path center 5f can be freely adjusted by moving the lens integrated prism 4 in the direction of the optical path center 5a. Further, the angle of the optical path center 5f in the horizontal plane can be adjusted by moving the lens integrated prism 4 in a direction perpendicular to the optical path center 5a in the horizontal plane of the substrate 1. As described above, the adjusted angle can be maintained by curing the bonding member 3 after adjusting the angle.

  As described above, the optical component of the present embodiment freely controls the angle of the optical path center 5f of the outgoing beam which is the light emitted from the optical component by moving the lens integrated prism 4 horizontally on the prism 2. be able to. If the outgoing beam is collimated light, swinging the beam angle is equivalent to controlling the position of the image condensed by the lens, and corresponds to the position control of the optical path. Even in the case of non-collimated light, changing the angle of the optical path center corresponds to the fact that the positions of the real image and the virtual image can be controlled, which is sufficiently useful. For this reason, it is not a requirement that the outgoing beam is collimated light.

  Further, when non-collimated light is converted into collimated light by a lens, it is generally impossible to move the lens in the optical axis direction due to the focal length. However, in the optical component of the present embodiment, when the mirror surface 2a of the prism 2 and the mirror surface 4a of the lens-integrated prism 4 are parallel, the lens is moved in the direction of the optical path center 5a. The collimating condition can be satisfied. That is, since the sum of the distances between the optical path center 5d and the optical path center 5e can be fixed regardless of the horizontal relative position of the lens integrated prism 4 and the prism 2 in the optical path direction, it is possible to realize a collimated state of the emitted beam. Easy.

  Since the control described above can be realized by moving the lens-integrated prism 4 only on the prism 2 in the horizontal direction, it is not necessary to increase the thickness of the joining member 3. For this reason, the shrinkage | contraction at the time of the joining member 3 hardening | curing can be suppressed, and the mounting with a high positional accuracy can be expected.

  Here, the optical module in the optical communication device is taken as an example of the device to which the optical component of the present embodiment is applied, but the device to which the optical component of the present embodiment is applied is an optical module in the optical communication device. The present invention is not limited to this and can be applied to devices in various fields using an optical system. As an example, the present invention may be applied to a small camera, a sensor such as a lidar, and a processing laser for focusing a laser array.

  1 shows an example in which a convex lens surface is formed on the lens-integrated prism 4, a concave lens surface may be formed on the lens-integrated prism 4. The lens-integrated prism 4 is not limited to the one that is integrally molded, and may be any lens that has a fixed relative height between the center of the lens and the center of the prism. May be fixed to a common substrate.

Embodiment 2. FIG.
FIG. 5 is a sectional view of an optical component according to the second embodiment of the present invention. The present embodiment is a modification of the first embodiment. As shown in FIG. 5, the optical component according to the present embodiment includes a base 6 disposed in contact with the substrate 1 and a lens 7 disposed in contact with the base 6 in addition to the optical component according to the first embodiment. doing. As shown in FIG. 5, the lower surface of the table 6 is in contact with the substrate upper surface 1 a, and the upper surface of the table 6 is in contact with the lens 7. In the present embodiment, when the lens of the lens-integrated prism 4 is called a first lens, the lens 7 is a second lens. The lens 7 is disposed so as to face the lens surface 4 b of the lens integrated prism 4. The lens 7 is disposed at a position where it can receive light emitted from the lens surface 4b. Constituent elements similar to those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and redundant description is omitted. Hereinafter, differences from the first embodiment will be described.

  In the case of the first embodiment, when the light emitted from the lens surface 4b is not collimated light, the formation positions of the real image and the virtual image of the emitted light by moving the lens integrated prism 4 in the optical axis direction, that is, the optical path center 5a direction. Shifts in the direction of the optical axis. By moving the lens 7 in the optical axis direction, the formation positions of the real image and the virtual image can be corrected. The optical axis of the lens 7 is preferably parallel to the substrate upper surface 1a. In addition, according to the present embodiment, it is possible to flexibly adjust the light beam shape in the optical axis direction, such as returning the light beam collected on the lens surface 4b back to collimated light.

  In the configuration example of FIG. 5, the lens 7 is disposed on the base 6, but the base 6 is not essential, and the base 6 may be shared with the prism 2, and the lens 7 is directly attached to the substrate 1. Alternatively, the step formed on the substrate 1 may be used in place of the base 6.

Embodiment 3 FIG.
FIG. 6 is a cross-sectional view of an optical component according to Embodiment 3 of the present invention. The present embodiment is a modification of the first embodiment. As shown in FIG. 6, the optical component of the present embodiment is obtained by adding a prism 8 disposed in contact with the substrate 1 and a prism 9 disposed in contact with the prism 8 to the optical component of the first embodiment. ing. As shown in FIG. 6, the lower surface of the prism 8 is in contact with the substrate upper surface 1 a, and the upper surface of the prism 8 is in contact with the prism 9. The prism 9 is disposed at a position where it can receive light emitted from the lens surface 4b. In the present embodiment, when the prism 2 is called a first prism, the prism 8 is a second prism and the prism 9 is a third prism. Constituent elements similar to those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and redundant description is omitted. Hereinafter, differences from the first embodiment will be described.

  The mirror surfaces of the prism 8 and the prism 9 are not parallel to the substrate upper surface 1a. The mirror surface of the prism 8 and the mirror surface of the prism 9 do not have to be parallel. In the present embodiment, the optical axis moved upward by the prism 2 and the lens integrated prism 4 can be returned downward. The alignment of the height of the optical axis is the basis of the optical system, and the height adjustment is a particularly important factor in an optical module in which the position of the exit window is defined. The optical directions of the prism 8 and the prism 9 in the horizontal direction, that is, in the ZX plane, do not have to coincide with each other. For example, by rotating the optical axis of the prism 9 about the Y axis with respect to the optical axis of the prism 8, the horizontal direction of the outgoing beam from the optical component of the present embodiment can be swung left and right. The prisms 8 and 9 are not necessarily arranged separately, and may be arranged on the substrate 1 as an integral parallel prism.

Embodiment 4 FIG.
FIG. 7 is a cross-sectional view of an optical component according to Embodiment 4 of the present invention. The present embodiment is a modification of the first embodiment. As shown in FIG. 7, the optical component of the present embodiment includes a step 10 disposed in contact with the substrate 1 and a submount 11 disposed in contact with the step 10 in the optical component of the first embodiment. An LD 12 that is a light emitting element disposed in contact with the submount 11 and a lens 13 disposed in contact with the substrate 1 are added. As shown in FIG. 7, the lower surface of the step 10 is in contact with the substrate upper surface 1 a, the upper surface of the step 10 is in contact with the lower surface of the submount 11, and the upper surface of the submount 11 is in contact with the LD 12. The lens 13 is disposed at a position where the light emitted from the LD 12 can be received, and the prism 2 is disposed at a position where the light emitted from the lens 13 can be received. In the present embodiment, when the lens of the lens-integrated prism 4 is called a first lens, the lens 13 is a second lens. The lens 13 is disposed so as to face the prism 2. Constituent elements similar to those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and redundant description is omitted. Hereinafter, differences from the first embodiment will be described.

  In the first embodiment, when a light beam having a wide outgoing divergence angle is incident, light passing through a portion other than the joint portion of the prism 2 and the lens integrated prism 4 cannot adjust the outgoing optical path, resulting in so-called vignetting loss. In the present embodiment, even when the LD 12 that generates light having a large emission divergence angle is used as the light source, the light output from the LD 12 is converted into a light flux having a narrow emission divergence angle by the lens 13, thereby reducing vignetting loss. Can be suppressed. Usually, the LD 12, the submount 11, the step 10, the prism 2, and the lens integrated prism 4 have a height tolerance. However, as described in the first embodiment, the optical axis shift due to the height tolerance is integrated with the lens. Correction can be made by moving the prism 4 in the direction of the optical path center 5a. Further, by arranging each member so that the light output from the LD 12 is condensed after passing through the lens 13, vignetting loss in the prism 2 and the lens integrated prism 4 can be reduced.

  In the present embodiment, the height of the optical axis of the LD 12 is lower than the height of the optical axis after passing through the lens-integrated prism 4, so that when the optical component is mounted as a package, the LD 12 is close to the bottom surface of the package. It is easy to dissipate the heat generated by the LD 12 to the outside of the package.

  In the present embodiment, an example in which the light incident source is the LD 12 has been described. However, the light incident source is not limited to the LD 12, and the light incident source is a waveguide of a multiplexer chip, a waveguide type light receiving element, a side incident type light receiving element, The adjustment method using the lens 13 described above can also be applied to a fiber or the like. In the present embodiment, an example in which the incident direction of light is horizontal to the substrate 1 has been described. However, even when the incident direction of light is perpendicular to the substrate 1, the optical path parallel to the substrate 1 is reflected by a mirror or the like. By doing so, the same adjustment is possible.

  The step 10 is used to correct the difference in height between the LD 12 and the submount 11 and the lens 13, but the step 10 may not be provided if it is not necessary to correct the difference in height. .

  Further, the number of LDs and submounts is not limited to one, and a plurality of LDs and submounts may be arranged in parallel. FIG. 8 is a top view of the optical component of the present embodiment including a plurality of LDs and submounts. As shown in FIG. 8, the submounts 11-1 to 11-4 are arranged in parallel on the step 10, and the LDs 12-1 to 12-4 are arranged on the submounts 11-1 to 11-4. . The lenses 13-1 to 13-4 are arranged on the substrate 1 and the lens integrated prisms 4-1 to 4-4 are arranged on the prism 2 corresponding to the LDs 12-1 to 12-4, respectively. Arranging a plurality of LDs and submounts in parallel in this way is generally performed in integrated optical modules, and this facilitates input / output of high-frequency electrical signals to each LD. In order to suppress variations in the height direction, it is desirable to make the step 10 common. More preferably, the submount 11 is made common and each LD is flip-arranged thereon, or a plurality of output channel ports can be integrated in the LD itself. Since the LD has a plurality of output channel ports, it can be coupled to a multi-core fiber or aggregated by a multiplexer, and the transmission capacity can be increased. In particular, if the LDs can be arranged in a state where the relative heights and the relative intervals of the plurality of output channel ports are precisely matched, the lens array can be used to mount them together, improving convenience. Further, the lenses 13-1 to 13-4 may be micro lens arrays. Although FIG. 8 shows an example in which four LDs and submounts are provided, the number of LDs and submounts is not limited to four.

Embodiment 5. FIG.
FIG. 9 is a cross-sectional view of an optical component according to Embodiment 5 of the present invention. This embodiment is a modification of the fourth embodiment. As shown in FIG. 9, in the optical component of the present embodiment, a monitor PD 14 that is a light receiving element for measuring the light intensity is added to the optical component of the fourth embodiment. The active layer surface of the monitor PD 14 is parallel to the substrate 1. In FIG. 9, the structure used for fixing the monitor PD 14 is not shown. Any method may be used for fixing the monitor PD 14, but as an example, a method of placing a monitor pedestal with a pier on the substrate 1 and attaching the monitor PD 14 on the pier can be used. Constituent elements similar to those in the fourth embodiment are denoted by the same reference numerals as those in the fourth embodiment, and redundant description is omitted. Hereinafter, differences from the fourth embodiment will be described.

  In the present embodiment, the reflectance of the mirror surface 4a of the lens-integrated mirror 4 is slightly lowered, and light incident on the mirror surface 4a is transmitted at a certain ratio. Thereby, a part of the light output from the LD 12 is emitted above the lens integrated mirror 4. The monitor PD 14 disposed so as to face the upper surface of the lens-integrated mirror 4 receives the light emitted above the lens-integrated mirror 4 so that the light intensity of the LD 12 can be monitored. In the optical module, the monitor PD 14 for monitoring the light intensity of the LD 12 is necessary. A driver may be arranged behind the LD 12, that is, in the −Z direction. In this case, it is difficult to arrange the monitor PD behind. When the monitor PD is arranged in the front direction, that is, in the Z direction, it is generally necessary to add a prism to partially divide the optical path. However, since the optical component of the present embodiment already includes the lens integrated prism 4, a new prism is provided. The front arrangement of the monitor PD 14 can be easily realized without adding.

  Further, since the real image of the LD 12 by the lens 13 can be arranged on the monitor PD 14, the size of the monitor PD 14 can be reduced as compared with the case where the lens 13 is not provided, and stray light can be suppressed and the cost of the monitor PD can be reduced. can do. Further, position adjustment can be performed based on the light intensity monitored by the monitor PD 14. For example, when the light intensity monitored by the monitor PD 14 is small, it is considered that the positional deviation is large. Therefore, the position adjustment can be performed by moving the lens integrated mirror 4 so that the light intensity becomes large.

Embodiment 6 FIG.
FIG. 10 is a cross-sectional view of an optical component according to Embodiment 6 of the present invention. This embodiment is a modification of the fourth embodiment. As shown in FIG. 10, in the optical component of the present embodiment, a table 15 that contacts the substrate 1, a lens 16 that contacts the table 15, and a waveguide 17 are added to the optical component of the fourth embodiment. In the present embodiment, observation devices 18 and 19 for observing incident light are used during manufacturing. As shown in FIG. 10, the lower surface of the table 15 is in contact with the substrate upper surface 1 a, and the upper surface of the table 15 is in contact with the lens 16 and the waveguide 17. The lens 16 is disposed at a position where the light emitted from the lens surface 4b can be received, and the waveguide 17 is disposed at a position where the light emitted from the lens 16 can be received. In the present embodiment, when the lens of the lens integrated prism 4 is referred to as a first lens and the lens 13 is referred to as a second lens, the lens 16 is a third lens. The lens 16 is disposed so as to face the lens surface 4 b of the lens integrated prism 4. The waveguide 17 is disposed on the exit side of the lens 16 so as to face the lens 16. Constituent elements similar to those in the fourth embodiment are denoted by the same reference numerals as those in the fourth embodiment, and redundant description is omitted. Hereinafter, differences from the fourth embodiment will be described.

  In the present embodiment, when the light emitted from the LD 12 and transmitted through the lens surface 4 b is collimated light, the lens 16 collects the light emitted from the lens surface 4 b and makes it incident on the waveguide 17. When the light after passing through the lens surface 4b is non-collimated light, the lens 16 may not be provided. Since the observation devices 18 and 19 are used only at the time of manufacture, the observation devices 18 and 19 may not be components of the optical component, the optical module, and the method for manufacturing the optical component.

  The optical axis can be adjusted by moving the lens integrated prism 4 and the lens 16 in the horizontal direction after fixing the arrangement of the LD 12 and the waveguide 17. Here, the reflectance of the mirror surface 4a of the lens-integrated prism 4 is slightly lowered, and light incident on the mirror surface 4a is transmitted at a certain ratio. When the observation devices 18 and 19 are arranged in the direction of the side surface and the upper surface of the lens integrated prism 4, the deviation between the optical axis of the emitted light from the LD 12 and the optical axis of the emission end surface of the waveguide 17 can be observed. Specifically, the light emitted from the LD 12 is condensed onto the end face of the waveguide 17 by the lens 16. The condensed light is scattered by the end face of the waveguide 17, and the light can be observed by the observation device 18 through the lens-integrated prism 4. Here, when light is emitted from the waveguide 17 in the opposite direction, that is, in the −Z direction, the emitted light passes through the lens-integrated prism 4 and can be observed by the observation device 18. As a result, the observation device 18 can observe both the light emitted from the LD 12 and the light emitted from the waveguide 17, and the optical axes of both can be adjusted. When the observation device 19 is used, it is possible to observe the light emitted from the waveguide 17 and condensed by the end face of the LD 12 and scattered, and the light emitted from the LD 12. Either one or both of the observation device 18 and the observation device 19 may be used.

Embodiment 7 FIG.
Next, an optical component according to Embodiment 7 of the present invention will be described. In this embodiment, the optical component described in Embodiments 1 to 6 is sealed in a metal or resin package. Thereby, airtightness can be ensured, impact can be absorbed, it is easy to carry, and effects such as easy connection to other parts can be obtained.

  The configuration described in the above embodiment shows an example of the contents of the present invention, and can be combined with another known technique, and can be combined with other configurations without departing from the gist of the present invention. It is also possible to omit or change the part.

DESCRIPTION OF SYMBOLS 1 board | substrate, 1a board | substrate upper surface, 2,8,9 prism, 2a, 4a mirror surface, 2b prism upper surface, 2c, 4d prism lower surface, 3 joining member, 4,4-1-4-4 lens integrated prism, 4b lens Surface, 4c lens main surface, 5a, 5b, 5c, 5d, 5e, 5f optical path center, 6, 15 units, 7, 13, 13-1 to 13-4, 16 lens, 10 steps, 11, 11-1 to 11-4 Submount, 12, 12-1 to 12-4 LD, 14
Monitor PD, 17 waveguide.

Claims (15)

A substrate,
A prism disposed in contact with the upper surface of the substrate;
A lens-integrated prism obtained by integrating a lens and a prism;
A joining member that transmits light;
With
The prism and the lens-integrated prism are bonded via the bonding member,
A lower surface that is a surface on the prism side of the lens-integrated prism, a lower surface that is a surface in contact with the upper surface of the substrate of the prism, and an upper surface of the prism are parallel to the upper surface of the substrate;
The lens-integrated prism and the mirror surface of the prism are each non-parallel to the upper surface of the substrate and non-parallel to the optical axis of the lens of the lens-integrated prism,
An optical component, wherein an optical path center of light incident on the prism is parallel to an upper surface of the substrate, and an optical axis of a lens of the lens integrated prism is parallel to an upper surface of the substrate.   The optical component according to claim 1, wherein the bonding member is a thermosetting bonding agent or an ultraviolet curable bonding agent.   The optical component according to claim 1, wherein a lens of the lens-integrated prism is a convex lens.   The optical component according to claim 1, wherein the lens of the lens-integrated prism is a concave lens. A second lens arranged to face the lens surface of the first lens which is a lens of the lens-integrated prism;
Further comprising
The second lens is disposed on an upper surface of the substrate;
5. The optical component according to claim 1, wherein an optical axis of the second lens is parallel to an upper surface of the substrate. A table disposed on an upper surface of the substrate;
A second lens arranged to face the lens surface of the first lens which is a lens of the lens-integrated prism;
Further comprising
The second lens is disposed on an upper surface of the table;
5. The optical component according to claim 1, wherein an optical axis of the second lens is parallel to an upper surface of the substrate. The prism is a first prism,
A second prism disposed in contact with the upper surface of the substrate;
A third prism disposed in contact with the upper surface of the second prism;
Further comprising
5. The optical component according to claim 1, wherein mirror surfaces of the second prism and the third prism are each non-parallel to the substrate. 6. The lens of the lens integrated prism is a first lens,
A light emitting element;
A second lens that collects the light emitted from the light emitting element and enters the prism;
The optical component according to claim 1, further comprising:   The optical component according to claim 8, comprising a plurality of the lens integrated prism, the second lens, and the light emitting element. A light receiving element arranged to face the upper surface of the prism;
Further comprising
The optical component according to claim 8, wherein an active layer surface of the light receiving element is parallel to the substrate. A third lens arranged to face the lens surface of the first lens;
A waveguide disposed on the exit side of the third lens so as to face the lens surface of the third lens;
The optical component according to claim 8, further comprising:   The optical component according to claim 1, wherein a mirror surface of the lens-integrated prism and a mirror surface of the prism are parallel to each other.   The optical component according to claim 1, wherein the optical component is sealed in a metal or resin package.   An optical module comprising the optical component according to claim 1. An optical component manufacturing method comprising:
A first step of disposing a prism in contact with the upper surface of the substrate and disposing a bonding member for bonding the prism and the lens-integrated prism;
Before the bonding member is cured, the lens integrated prism is disposed in contact with the bonding member, and the lens integrated prism is emitted from the optical component by moving in the optical axis direction of incident light of the optical component. A second step of adjusting the elevation angle of the light
A third step of curing the joining member after the second step;
The bonding member is a member that transmits light,
A lower surface that is a surface on the prism side of the lens-integrated prism, a lower surface that is a surface in contact with the upper surface of the substrate of the prism, and an upper surface of the prism are parallel to the upper surface of the substrate;
The lens-integrated prism and the mirror surface of the prism are each non-parallel to the substrate and non-parallel to the optical axis of the lens of the lens-integrated prism,
An optical component manufacturing method, wherein an optical path center of light incident on the prism is parallel to an upper surface of the substrate, and an optical axis of a lens of the lens-integrated prism is parallel to an upper surface of the substrate.

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