KR0156967B1 - Optical collimater and optical device using that - Google Patents

Abstract

Disclosed are an optical collimator capable of reducing optical loss due to misalignment and an optical component using the same. The optical collimator of the present invention is composed of an optical fiber formed by joining a single mode optical fiber and a multimode optical fiber, and a lens spaced apart from or attached to the multimode optical fiber by a predetermined distance. In addition, an optical component using the optical collimator of the present invention is provided. According to the present invention, the problem of misalignment between the collimator and the decollimator can be improved to greatly reduce the optical loss due to misalignment of the optical parts.

Description

Optical collimator and optical component using same

1 is a diagram for explaining an optical connector using a conventional optical collimator.

2 is a diagram illustrating an optical connector using an optical collimator according to the present invention.

3 is a view showing an optical attenuator using the collimator of the present invention.

The present invention relates to an optical collimator used in optical applications such as an optical transmission system and an optical component using the same, and more particularly, to an optical collimator and an optical component using the same, which can reduce optical loss due to misalignment. It is about.

In general, active components such as a light source and a photodetector and an optical fiber are incomplete as optical system components in the optical communication field, and a cabling technique, a connector technique, and an optical transmission technique are required, and thus an optical collimator is used as an optical transmission component used in the optical transmission technique. It is used.

1 is a diagram for explaining an optical connector using a conventional optical collimator.

First, the configuration of an optical connector using a conventional optical collimator will be described with reference to FIG. Conventional optical connectors can be broadly classified into collimators (A) on which light is incident and decollimators (B) which receive light, and change the collimator (A) and collimator (B) by changing the incident direction of light. ) Are interchanged. In addition, the collimator (A) is composed of a first optical fiber (1) and a first lens (3) consisting of a clad layer (1a) and a core layer (1b), the decollimator (B) is a cladding layer (5a) and It consists of the 2nd optical fiber 5 which consists of the core layer 5b, and the 2nd lens 7. As shown in FIG.

Next, focusing of light using an optical connector including a conventional optical collimator will be described. In the conventional optical connector, the first lens 3 is installed in the single mode first optical fiber 1 having the diameter of the core layer 1b of about 9 μm, and the parallel light 9 is removed through the second lens 7. 2 Focus on the optical fiber (5). In other words, in the case of the optical connector composed of the collimator A and the decollimator B, the light 11 emitted from the core layer 1b of the first optical fiber 1 of the collimator A is inherently opened to the air. It proceeds with a numerical aperture (NA) and passes through the first lens 3 to become parallel light 9. The parallel light 9 passes through the second lens 7 again and is focused on the core layer 5b of the second optical fiber 5. At this time, since the core layer 5b of the second optical fiber 5 is a single mode optical fiber having a diameter of about 9 μm, the optical loss due to misalignment when the collimator A and the decollimator B are aligned is several decibels or more. There is a problem.

In addition, in order to reduce the optical loss, a precision device capable of precise alignment of the collimator (A) and the decollimator (B) is required, which causes an increase in the price of the optical connector.

Accordingly, it is an object of the present invention to provide an optical collimator capable of reducing light loss and an optical component using the same.

In order to achieve the above object, the present invention,

An optical fiber composed of a single mode optical fiber and a multimode optical fiber bonded together; And it provides an optical collimator comprising a lens spaced apart or attached to a predetermined distance to the multi-mode optical fiber.

The lens makes the optical signal output from the optical fiber into parallel light, and the single mode optical fiber and the multimode optical fiber are joined by fusion splicing, respectively.

In addition, the present invention,

A collimator composed of a first optical fiber and a first lens composed of a single mode optical fiber and a multimode optical fiber and to which an optical signal is input; And

The optical connector is spaced apart from the fraud collimator, and comprises a second optical fiber composed of a multimode optical fiber and a single mode optical fiber and a decollimator configured to receive the optical signal.

The first optical fiber, the first lens, the second optical collimator and the second lens are spaced apart from each other by a predetermined distance, and the first lens and the second lens are used to make the optical signal into parallel light.

In addition, the single mode optical fiber and the multimode optical fiber of the first optical fiber and the second optical fiber are bonded by fusion splicing, respectively.

In addition, the present invention,

A collimator composed of a first optical fiber and a first lens composed of a single mode optical fiber and a multimode optical fiber and to which an optical signal is input;

A first holder fixedly supporting the collimator;

A collimator spaced apart from the collimator by a predetermined distance and configured to receive the optical signal by a second optical fiber and a second lens including a multimode optical fiber and a single mode optical fiber; And

It provides a light attenuator comprising a second holder that can be fixed to the collimator and rotate about the collimator to change the relative angle between the collimator and the collimator.

The first holder can rotate with respect to the decollimator, and the single mode and multimode optical fibers of the first and second optical fibers are bonded by fusion bonding, respectively.

Moreover, according to another example of this invention, this invention is

A collimator composed of a first optical fiber and a first lens composed of a single mode optical fiber and a multimode optical fiber and to which an optical signal is input;

A collimator spaced apart from the collimator by a predetermined distance and configured to receive the optical signal by a second optical fiber and a second lens including a multimode optical fiber and a single mode optical fiber; And

A light attenuator is provided between the collimator and the decollimator by providing a blocker or attenuating film to attenuate light.

In addition, the present invention,

Light source;

A lens configured to be spaced apart from the light source by a predetermined distance; And

An optical connector, comprising: an optical fiber spaced apart from or attached to the lens by a predetermined distance and composed of a multimode optical fiber and a single mode junction.

The light source is composed of a laser diode or a light emission diode.

According to the present invention, by improving the problem of misalignment between the collimator and the decollimator, it is possible to greatly reduce the optical loss due to misalignment of the single-mode optical connector, by using the optical collimator according to the present invention Attenuator and optical concentrator can be manufactured.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

2 is a diagram illustrating an optical connector using an optical collimator according to the present invention.

First, with reference to FIG. 2, the structure of an optical connector using the optical collimator according to the present invention will be described. The optical connector according to the present invention can be broadly classified into a collimator (C) on the light incident side (incident side) and a decollimator (D) on which light is received (receive side), and the incident direction of light In other words, the collimator C and the decollimator D are interchanged. In the collimator C, a single mode optical fiber 21 composed of a cladding layer 21a and a core layer 21b and a multimode optical fiber 23 composed of a cladding layer 23a and a core layer 23b are used for fusion bonding. The first lenses 25 are provided on the entire surfaces of the first optical fibers 21 and 23 and the multi-mode optical fibers 23 bonded by the first optical fibers 21 and 23. The decollimator D is a single mode optical fiber 27 composed of a cladding layer 27a and a core layer 27b and a multimode optical fiber 29 composed of a cladding layer 29a and a core layer 29b by fusion bonding. A second lens 31 is provided on the front surfaces of the second optical fibers 27 and 29 bonded to each other and the multimode optical fiber 29. Reference numerals 22a and 22b show joints formed by fusion splicing. In the present exemplary embodiment, the first optical fibers 21 and 23, the first lens 25, and the second optical fibers 27 and 29 and the second lens 31 are spaced apart from each other by a predetermined distance.

Next, focusing of light using the optical collimator according to the present invention will be described. The optical collimator of the present invention is fusion splicing the same diameter multimode optical fibers 23, 29 at the ends of the single mode optical fibers 21, 27 to solve the conventional mismatch. As described above, after the boundary surfaces of the single mode optical fibers 21 and 27 and the multi mode optical fibers 23 and 29 are tapered, the lenses 25 and 31 are disposed on the cross sections of the multi mode optical fibers 23 and 29 to provide parallel light. And transmit the light using it.

More specifically, the optical connector of the present invention passes through the core layer 21b of the single mode optical fiber 21 of the collimator C, and the light emitted from the cross section of the core layer 23b of the multimode optical fiber 23. Reference numeral 33 is a parallel light 35 after passing through the first lens 25 while traveling in the air with a unique numerical aperture (NA). The parallel light 35 passes through the second lens 31 of the decollimator D and is then focused on the core layer 29b of the multimode optical fiber 29. It focuses to the core layer 27b. In this case, since the light focused from the second lens 31 of the decollimator D proceeds to the multi-mode optical fiber 29 whose diameter of the core layer 29b is 50 µm or more, the light loss becomes very small. As a result of experiments by the present inventors, the optical loss of about 1 decibel when the light enters the core layer of the single mode optical fiber from the multimode optical fiber. According to the present invention, since the problem of misalignment, which is a problem in the prior art, is greatly improved, the optical loss due to misalignment of the single mode optical connector can be greatly reduced.

On the other hand, in the optical transmission system, the optical signal is transmitted at high power, and the optical signal transmitted at high power is attenuated by the optical attenuator in order to be properly used at the receiving side. The optical attenuator for attenuating the high power optical signal can be used to adjust and calibrate the optical communication system, to measure various kinds or to adjust the interval loss of the optical fiber transmission path.

3 is a view showing an optical attenuator using the collimator of the present invention.

Referring to FIG. 3, the optical attenuator according to the present invention attenuates an optical signal by using a displacement of an axis between the first optical fibers 41 and 43 and the second optical fibers 45 and 47. The optical attenuator includes first and second optical fibers 41 and 43 composed of a single mode optical fiber 41 and a multimode optical fiber 43, and second optical fibers 45 and 47 composed of a single mode optical fiber 45 and a multimode optical fiber 47. Are spaced apart by a predetermined distance, and a first lens 49 and a second lens 51 of a predetermined form arranged in front of each of the optical fibers are provided.

The first optical fibers 41 and 43 and the first lens 49 constitute a collimator through which light is incident, and the second optical fibers 45 and 47 and the second lens 51 receive a collimator that receives an optical signal. Configure In addition, a first holder 53 and a second holder 55 for holding the first optical fibers 41 and 43 and the second optical fibers 45 and 47 are provided, and reference numeral 57 denotes an outer cylinder. In the present embodiment, the second optical fibers 45 and 47 including the second holder 55 and the second lens 51 may rotate, but the first optical fiber 41 including the first holder 53 may rotate. 43 and the first lens 49 may rotate.

In addition, the basic operation of the optical attenuator according to the present invention is the first optical fiber (41, 43) when rotating the second holder 55 and the second lens 51 including the second optical fiber (45, 47) about the rotation axis It is made by the axis shift | deviation with and.

In particular, the optical attenuator according to the present embodiment is a variable optical attenuator for fixing one side of the holder and rotating the other side to vary the loss of the side, or to block the light by installing a blocker or attenuating film between the collimator and the collimator. It may be.

As described above, according to the present invention, the problem of misalignment between the collimator and the decollimator can be improved to greatly reduce the optical loss due to the mismatch of the single mode optical connector. In the embodiment of the present invention, only the optical connector and the optical attenuator are disclosed using the optical collimator, but the optical concentrator may be manufactured using the optical collimator of the present invention.

As mentioned above, although embodiment of this invention was described concretely, this invention is not limited to this, A deformation | transformation and improvement are possible in the range of common knowledge of a person skilled in the art.

Claims (13)

An optical fiber composed of a single mode optical fiber and a multimode optical fiber bonded together; And a lens spaced apart from or attached to the multi-mode optical fiber by a predetermined distance. The optical collimator of claim 1, wherein the lens converts an optical signal into parallel light. The optical collimator according to claim 1, wherein the single mode optical fiber and the multimode optical fiber are joined by fusion splicing, respectively. A collimator composed of a first optical fiber and a first lens composed of a single mode optical fiber and a multimode optical fiber and to which an optical signal is input; And a collimator spaced apart from the collimator by a predetermined distance, the second optical fiber comprising a multimode optical fiber and a single mode optical fiber, and a second lens configured to receive the optical signal. The optical connector according to claim 4, wherein the first optical fiber, the first lens, and the second optical fiber and the second lens are spaced apart from each other by a predetermined distance. The optical connector of claim 4, wherein the first lens and the second lens make the optical signal into parallel light. 5. The optical connector according to claim 4, wherein the single mode optical fiber and the multimode optical fiber of the first optical fiber and the second optical fiber are bonded by fusion splicing, respectively. A collimator composed of a first optical fiber and a first lens composed of a single mode optical fiber and a multimode optical fiber and to which an optical signal is input; A first holder fixedly supporting the collimator; A collimator spaced apart from the collimator by a predetermined distance and configured to receive the optical signal by a second optical fiber and a second lens including a multimode optical fiber and a single mode optical fiber; And a second holder fixed to the collimator and rotating relative to the collimator to change a relative angle between the collimator and the collimator. 9. The optical attenuator of claim 8, wherein the first holder is rotatable relative to the decollimator. The optical attenuator according to claim 8, wherein the single mode optical fiber and the multimode optical fiber of the first optical fiber and the second optical fiber are bonded by fusion bonding, respectively. A collimator composed of a first optical fiber and a lens composed of a single mode optical fiber and a multimode optical fiber, and receiving an optical signal; A collimator spaced apart from the collimator by a predetermined distance and configured to receive the optical signal by a second optical fiber and a second lens including a multimode optical fiber and a single mode optical fiber; And a blocker or an attenuation film between the collimator and the decollimator to attenuate light. Light source; A lens configured to be spaced apart from the light source by a predetermined distance; And an optical fiber spaced apart from or attached to the lens by a predetermined distance and composed of a multimode optical fiber and a single mode junction. 13. The light concentrator according to claim 12, wherein the light source is composed of a laser diode or a light emission diode.