JPH04284401A - Microlens and microlens array - Google Patents

Abstract

PURPOSE:To facilitate the production of the microlens and microlens array and to reduce the size thereof. CONSTITUTION:This lens has a 1st rod lens 1 having, for example, a columnar shape, a 2nd rod lens 2 which has a columnar shape and is so provided as to parallel the central axis thereof with the central axis of the 1st rod lens 1 and a 3rd rod lens 3 which has a columnar shape and is so provide as to position the central axis thereof perpendicularly to the plane inclusive of the central axis of the 1st rod lens 1 and the central axis of the 2nd rod lens 2 and to bring the circular columnar surface thereof into contact with the circular columnar surfaces of the 1st and 2nd rod lenses 1, 2.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to microlenses and microlens arrays.

[0002] In the field of optical communication or optical transmission, optical semiconductor devices such as semiconductor lasers used as light sources are modulated directly or indirectly, and the modulated light is transmitted to the receiving side through optical fibers. I have to. When optically coupling an optical semiconductor element and an optical fiber, the output beam parameters of the optical semiconductor element and the input beam parameters of the optical fiber are different, and high optical coupling efficiency cannot be obtained by simply placing the optical semiconductor element and the optical fiber close together. Since this is not possible, generally the light emitted from the optical semiconductor element is converted into a beam by a lens and then coupled to an optical fiber. Since the beam diameter of lenses used in this type of application is usually as small as 1 mm or less, this type of lens is called a microlens. Further, when optically coupling an optical semiconductor element array including a plurality of optical semiconductor elements to an optical fiber array including a plurality of optical fibers, a microlens array including a plurality of microlenses is used.

0003

[Prior Art and Problems to be Solved by the Invention] Ball lenses are one of the forms of microlenses, but miniaturization is difficult due to limitations in processing methods, lens handling methods, fixing methods, etc. There is a problem. In particular, when ball lenses are used in an array, the pitch between the lenses is limited by the diameter of the ball lenses. , it is virtually impossible to realize a microlens array consisting of ball lenses.

Another conventional form of microlens is a tapered spherical fiber, which has a lens function by heating and melting the tip of an optical fiber. Although tapered spherical fibers are effective for optically coupling a single optical fiber and a single semiconductor laser, they are time-consuming to manufacture, so there is a problem in that the number of manufacturing steps increases when arrayed.

[0005] As described above, the conventional technology has the problem that it is difficult to miniaturize or manufacture.

The present invention was created in view of the above circumstances, and an object of the present invention is to provide a microlens or a microlens array that is easy to downsize and easy to manufacture.

[0007]

[Means for Solving the Problems] The microlens of the present invention includes a first rod lens having a cylindrical shape, and a microlens having a cylindrical shape, the central axis of which is arranged parallel to the central axis of the first rod lens. a second rod lens having a cylindrical shape, whose central axis is perpendicular to a plane including the central axis of the first rod lens and the central axis of the second rod lens, and whose cylindrical surface is parallel to the first and second rod lenses. and a third rod lens provided so as to be in contact with the cylindrical surface of the two-rod lens.

The microlens array of the present invention includes a first rod lens having a cylindrical shape, and a second rod having a cylindrical shape and provided so that its central axis is parallel to the central axis of the first rod lens. a lens, which has a cylindrical shape, whose central axis is perpendicular to a plane containing the central axis of the first rod lens and the central axis of the second rod lens, and whose cylindrical surface is the cylinder of the first and second rod lenses; and a third rod lens array consisting of a plurality of rod lenses of the same diameter provided so as to be in contact with the surface.

Another microlens array of the present invention has a first rod that is cylindrical and is made up of a plurality of rod lenses with the same diameter, the central axes of which are located on the same plane and are parallel to each other. a lens array; and a plurality of cylinder-shaped lenses having the same diameter, the central axes of which are located on the same plane, and the central axes of which are parallel to the central axis of each rod lens of the first rod lens array. a second rod lens array consisting of rod lenses, and a rod lens of the second rod lens array that has a cylindrical shape and whose central axis corresponds to the central axis of the rod lens of the first rod lens array. a third rod consisting of a plurality of rod lenses of the same diameter, which are perpendicular to a plane containing the central axis and whose cylindrical surfaces are in contact with the cylindrical surfaces of each rod lens of the first and second rod lens arrays; and a lens array.

0010

[Operation] In the microlens of the present invention, the first rod lens and the second rod lens are parallel, and the central axis of the third rod lens is the central axis of the first rod lens and the central axis of the second rod lens. and the cylindrical surface of the third rod lens is in contact with the cylindrical surfaces of the first and second rod lenses, that is, the third rod lens is sandwiched between the first and second rod lenses. Since it is held, the optical semiconductor element and the optical fiber can be optically coupled by setting an optical path (optical axis) in a direction perpendicular to the central axes of the first, second, and third rod lenses.

Furthermore, since the first, second and third rod lenses, which are the constituent elements of the microlens of the present invention, each have a cylindrical shape, they can be easily miniaturized. can be easily manufactured.

In the microlens array of the present invention, a plurality of optical semiconductor elements and a plurality of optical fibers can be optically coupled by setting optical paths in the same manner as in the microlens of the present invention.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Examples of the present invention will be described below with reference to the drawings.

FIG. 1 is a perspective view of an optical coupling section of a light source module showing an embodiment of the microlens of the present invention. Reference numeral 1 denotes a cylindrical first rod lens provided on the optical semiconductor element 4 side including a semiconductor laser, a light emitting diode, and the like. A cylindrical second rod lens 2 is provided on the optical fiber 5 side for optical coupling, and its central axis is parallel to the central axis of the first rod lens 1. 3 is a cylindrical third rod lens held between the first rod lens 1 and the second rod lens 2, and its central axis is parallel to the central axis of the first rod lens 1 and the second rod lens 2. perpendicular to the plane containing the central axis of The cylindrical surface of the third rod lens 3 is in contact with the cylindrical surfaces of the first and second rod lenses 1 and 2.

First, second and third rod lenses 1, 2,
3 may be formed from a material with a uniform refractive index, but may have a refractive index distribution in the radial direction of the cylinder. In this embodiment, each rod lens uses an optical fiber having a diameter of 125 μm.

In the following explanation, the x-axis parallel to the central axes of the first and second rod lenses 1 and 2, the z-axis parallel to the central axis of the third rod lens 3, and the An orthogonal three-dimensional coordinate system consisting of a perpendicular y-axis is used.

According to the configuration of the microlens of this embodiment, the optical axes are set perpendicular to the central axes of the first, second, and third rod lenses 1, 2, and 3, that is, parallel to the y-axis, and the optical semiconductor The element 4 and the optical fiber 5 can be optically coupled.

FIG. 2 is a diagram for explaining the focusing effect of the microlens shown in FIG. 1, in which (A) is a view of the optical coupling section in FIG. FIG. 3 is a diagram of the optical coupling section viewed in the z-axis direction. When the light emitted from the optical semiconductor element 4 is viewed in the x-axis direction, this light is converted into a substantially parallel beam by the first rod lens 1, as shown in FIG. 2(A),
The light passes through the third rod lens 3, is focused by the second rod lens 2, and enters the optical fiber 5 from its core end face. Furthermore, when the light emitted from the optical semiconductor element 4 is viewed in the z-axis direction, this light is in the first direction as shown in FIG. 2(B).
After passing through the rod lens 1, it is focused by the third rod lens 3, passes through the second rod lens 2, and is connected to the optical fiber 5.
is incident from the end face of the core.

When the optical semiconductor element 4 is a light emitting diode, the distance d1 between the optical semiconductor element 4 and the first rod lens 1 is
, the distance d2 between the second rod lens 2 and the optical fiber 5
are 1 of the diameter of the first and second rod lenses 1 and 2, respectively.
/4 can be achieved. Therefore, when optical fibers with a diameter of 125 μm are used as the first and second rod lenses 1 and 2, d1 = d2 ≒ 30 μm
becomes.

In this embodiment, the first, second, and third rod lenses 1, 2, and 3 are formed from the same optical fiber, but the optical semiconductor element 4 is an optical semiconductor whose output beam is asymmetric, such as a semiconductor laser. In cases where such elements are used, the diameters and refractive indexes of the first, second, and third rod lenses 1, 2, and 3 may be made different to cope with this problem.

FIG. 3 is a perspective view of an optical coupling section of a light source array module showing an embodiment of the microlens array of the present invention. This microlens array has a first lens parallel to the x-axis.
and second rod lenses 1 and 2, and a plurality of (five in the illustrated example) third rod lenses 3-1 parallel to the z-axis and sandwiched between the first and second rod lenses 1 and 2. 2,3
, 4, and 5. In order to bring each rod lens of the third rod array 13 into contact with the first and second rod lenses 1 and 2, each rod lens of the third rod lens array 13 has the same diameter.

15 is five optical fibers 5-1, 2, 3,
4 and 5 are held so that their central axes are located on the same plane and in contact with each other. Reference numeral 14 denotes an optical semiconductor element array in which optical semiconductor elements 4-1, 2, 3, 4, and 5 are arranged at the same pitch as the fiber arrangement pitch of the optical fiber array 15.

In this embodiment, each rod lens of the third rod lens array 13 is formed from the same optical fiber as the optical fiber of the optical fiber array 15, and the rod lenses of the third rod lens array 13 are made in contact with each other. By arranging the fiber array pitch in the optical fiber array 15 and the third rod lens array 1
The rod lens arrangement pitch in No. 3 and the optical semiconductor element arrangement pitch in the optical semiconductor element array 14 are made to match. Thereby, it is possible to couple the corresponding optical semiconductor element and the optical fiber with high optical coupling efficiency.

As described above, according to this embodiment, by holding the rod lenses made of optical fibers in a predetermined positional relationship, it is possible to easily manufacture a microlens array in which the lens parts are arranged one-dimensionally. . Further, since it is possible to correspond to an optical fiber array having a structure in which optical fibers are closely connected, it is possible to realize a compact light source array module.

FIG. 4 is a perspective view of an optical coupling section of a light source array module showing another embodiment of the microlens array of the present invention. In this embodiment, the third rod lens array 1
First and second rod lens arrays 11 and 12 each consisting of five rod lenses are provided so as to sandwich 25
A microlens array is formed by arranging the lens parts in a lattice pattern. The first rod lens array 11 includes five first rod lenses 1-1, 2-2, and 1-1 with the same diameter, which are provided so that their central axes are located on the same plane and are parallel to each other.
3, 4, and 5, the second rod lens array 12 is
five second rod lenses 2-1 with the same diameter, whose central axes are located on the same plane and are provided so that the central axes are parallel to the central axes of each rod lens of the first rod lens array 11; It consists of 2, 3, 4, and 5.

Reference numeral 25 denotes an optical fiber array in which 25 optical fibers are arranged in a lattice shape with the centers of their end faces equally spaced, and 24 corresponds to the end faces of the optical fibers of the optical fiber array 25. This is an optical semiconductor element array that is provided with four optical semiconductor elements.

In this embodiment, each rod lens is constructed from the same optical fiber as the optical fiber of the optical fiber array 25, and adjacent rod lenses in each rod lens array are in contact with each other. Thereby, the arrangement pitch of the lens parts in the microlens array can be made to match the arrangement pitch of the optical fibers and optical semiconductor elements in the optical fiber array 25 and the optical semiconductor element array 24.

As described above, according to this embodiment, an optical semiconductor element array in which optical semiconductor elements are two-dimensionally arranged in a lattice pattern can be easily coupled to an optical fiber array. Further, in the same manner as in the previous embodiment, it is possible to downsize the device.

[0029]

[Effects of the Invention] As explained above, according to the present invention,
This has the effect of making it possible to provide microlenses and microlens arrays that are easy to manufacture and easy to downsize.

[Brief explanation of the drawing]

FIG. 1 is a perspective view of an optical coupling section of a light source module showing an embodiment of a microlens of the present invention.

FIG. 2 is an explanatory diagram of a focusing effect in the microlens shown in FIG. 1.

FIG. 3 is a perspective view of an optical coupling section of a light source array module showing an embodiment of a microlens array of the present invention.

FIG. 4 is a perspective view of an optical coupling section of a light source array module showing another embodiment of the microlens array of the present invention.

[Explanation of symbols]

1 First rod lens 2 Second rod lens 3 3rd rod lens 11 First rod lens array 12 Second rod lens array 13 Third rod lens array

Claims (5)

[Claims] Claim 1: A first rod lens having a cylindrical shape (
1) a second rod lens (2) having a cylindrical shape and provided with its central axis parallel to the central axis of the first rod lens (1); is perpendicular to a plane containing the central axis of the first rod lens (1) and the central axis of the second rod lens (2), and the cylindrical surface thereof is
2) A third rod lens (3) provided so as to be in contact with the cylindrical surface of the microlens. [Claim 2] A first rod lens having a cylindrical shape (
1) a second rod lens (2) having a cylindrical shape and provided with its central axis parallel to the central axis of the first rod lens (1); is perpendicular to a plane containing the central axis of the first rod lens (1) and the central axis of the second rod lens (2), and the cylindrical surface thereof is
2) A third rod lens array (
13) A microlens array comprising: 3. A first rod lens array (11) consisting of a plurality of rod lenses having the same diameter and having a cylindrical shape and having their central axes located on the same plane and parallel to each other; shape, the central axis of which is located on the same plane, and the central axis is the first rod lens array (
11) a second rod lens array (12) consisting of a plurality of rod lenses having the same diameter and arranged parallel to the central axis of each rod lens; The cylindrical surface is perpendicular to a plane containing the central axis of the rod lens of the lens array (11) and the central axis of the rod lens of the second rod lens array (12) corresponding to the rod lens, and the cylindrical surface thereof is A third rod lens array (13) comprising a plurality of rod lenses of the same diameter provided so as to be in contact with the cylindrical surface of each rod lens of the two rod lens arrays (11, 12). Microlens array. 4. The microlens according to claim 1 or the microlens array according to claim 2 or 3, wherein the rod lens is made of an optical fiber. 5. The microlens array according to claim 4, wherein adjacent rod lenses in the rod lens array are in contact with each other.