KR20030069437A - Apparatus for inspecting collimator property - Google Patents

Abstract

PURPOSE: An apparatus for inspecting a characteristic of a collimator is provided to enhance device reliability by inspecting partially the collimator. CONSTITUTION: An apparatus for inspecting a characteristic of a collimator includes the first collimator(10a), the second collimator(10b), an inspection table(21), a grip portion(22), a light supply portion(30), the first light reception portion(40), a measuring portion, and an image display portion(60). The first collimator has a couple of fibers. The second collimator has a single fiber. The grip portion is installed on the inspection table in order to grip the first and the second collimators. The light supply portion is coupled to the fiber of the first collimator in order to transfer a predetermined optical signal. The light reception portion is coupled to the second fiber in order to receive a value of the optical signal which is transferred to the second collimator through the first fiber. The measuring portion calculates an optical signal value of the first fiber and a return value to the second fiber. The image display portion displays a measured value of the measuring portion.

Description

Apparatus for inspecting collimator property}

The present invention relates to a collimator characteristic inspection apparatus.

A so-called collimator, an optical communication device, refers to a device that converts light incident through a light source into parallel light. Such collimators are generally employed as one part in various equipments requiring parallel light such as optical communication equipment or semiconductor equipment.

A typical collimator is a pigtail (12) and a green lens (14, Grin lens), a pigtail (12) and a green lens (14) arranged on a mutually coaxial line, as shown in Figs. 1A and 1B. ) Is a tubular glass tube (15, Glass tube) is accommodated and a metal sleeve (16, Metal sleeve) for protecting the glass tube 15 from the outside.

A pigtail 12 formed of a glass material is provided with a predetermined inclined surface 12a at one end thereof and a fiber for forming a light incidence path so that a predetermined light is incident at the other end thereof. Here, a case in which fibers are provided in pairs 13a and 13b is referred to as a dual collimator 10a (hereinafter referred to as a "first collimator"), and one fiber 13A is provided as a single collimator. (10b; hereafter referred to as " second collimator ") (see FIGS. 1A and 1B).

An inclined surface 14a similar to the inclined surface 12a of the pigtail 12 is formed at one end of the green lens 14 coaxially with the pigtail 12. The inclined surfaces 12a and 14a of the pigtail 12 and the green lens 14 are inclined to correspond to each other.

In order to manufacture the collimator 10 having such a configuration, first, the green lens 14 is inserted and fixed into the tubular glass tube 15. One end of the green lens 14 having the inclined surface 14a is inserted into the glass tube 15, and the other end of the green lens 14 is exposed to the outside of the glass tube 15 by a predetermined length.

When the green lens 14 is accommodated in one side of the glass tube 15, the pigtail 12 is inserted into the other side. The pigtail 12 is inclinedly disposed so as to correspond to the inclined surface 14a of the green lens 14 that has one end formed with the inclined surface 12a accommodated in the glass tube 15 and is already accommodated in the glass tube 15.

At this time, the inclined surface 12a of the pigtail 12 is inclined with respect to the inclined surface 14a of the green lens 14 while undergoing an alignment process so as to meet a predetermined optical characteristic condition, and then If the conditions are met, the pigtail 12 is fixed in the glass tube 15.

When the green lens 14 and the pigtail 12 are accommodated in the glass tube 15, the glass tube 15 is inserted into the tubular metal sleeve 16, and then the epoxy resin 17 is applied to the glass tube. The manufacturing of the collimators 10a and 10b is completed by fixing 15 and the metal sleeve 16 to each other.

However, the conventional first and second collimators 10a and 10b may be used individually, or may be used as a package in pairs, and optical characteristics of the collimators 10a and 10b (for example, transmitted insertion) There is a disadvantage that the reliability of the product is inevitably reduced because there is no separate device for inspecting loss.

Accordingly, it is an object of the present invention to provide a collimator characteristic inspection apparatus which can enhance the reliability of a product by partially inspecting the collimator.

1A and 1B are cross-sectional views of a dual collimator and a single collimator,

2 is a perspective view of a collimator inspection apparatus according to a first embodiment of the present invention,

3 is a schematic block diagram of a collimator inspection apparatus of FIG.

4 is a perspective view of a collimator inspection apparatus according to a second embodiment of the present invention,

5 is a schematic block diagram of the collimator inspection apparatus of FIG.

6 is a perspective view of a collimator inspection apparatus according to a third embodiment of the present invention,

7 is a schematic block diagram of the collimator inspection apparatus of FIG.

* Explanation of symbols for the main parts of the drawings

10: collimator 12: pigtail

13 green lens 15 glass tube

16: metal sleeve 20: inspection device

21: inspection table 22: gripping portion

30: light supply unit 40: light receiving unit

50: measuring instrument 60: image display unit

The object is, according to the present invention, a first collimator having a pair of fibers; A second collimator disposed coaxially with a predetermined distance from the first collimator and having a single fiber; An examination table; A holding part provided on the inspection table to hold the first and second collimators of the inspection object; An optical supply unit configured to be coupled to one fiber of the first collimator to transmit a predetermined optical signal; A first optical receiver coupled to a fiber of the second collimator to receive a value transmitted to the fiber of the second collimator by an optical signal incident to the first collimator; A measuring unit for calculating an optical signal value incident to the first collimator and a value returned to the second collimator; It is achieved by a collimator characteristic inspection device characterized in that it comprises an image display unit for displaying the instrument value.

Here, the measuring unit measures the Transmitted Insertion Loss by subtracting an optical signal value incident to one fiber of the first collimator and a value transmitted to the fiber of the second collimator.

The apparatus may further include a second light receiver coupled to the other fiber of the first collimator. In this case, the measuring device totally reflects the light signal value incident on one fiber of the first collimator and the second collimator. After that, the Reflected Insertion Loss may be measured by subtracting the value returned to the other fiber of the first collimator.

The apparatus may further include a non-polarization supply unit provided to be coupled to one side fiber of the first collimator to transmit a predetermined non-polarization optical signal to the first collimator. In this case, the measuring instrument may be supplied from the non-polarization supply unit. Of course, the polarization dependent loss is transmitted to the first light receiver through the first and second collimators.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In addition, since the present invention has been described with reference to FIGS. 1A and 1B described above, FIGS. 1A and 1B are replaced with those described above, and the same reference numerals are assigned to the same components related to FIGS.

The collimator characteristic inspection apparatus 20 according to the present invention is arranged coaxially with the first collimator 10a and the first collimator 10a having a pair of fibers 13a and 13b, as shown in FIG. 2. And a second collimator 10b having a single fiber 13A, a test table 21 and a test table 21 provided on the test table 21 to hold the first and second collimators 10a and 10b to be inspected. A branch 22, a light supply unit 30 for transmitting a predetermined optical signal to the first collimator 10, a first light receiver 40 for receiving an optical signal incident on the first collimator 10, Image measuring instrument 50, which calculates the optical signal value incident to the first collimator 10a and the value transmitted to the second collimator 10b, and is connected to the instrument 50 to display the value of the instrument 50 as an image The display unit 60 is provided.

The inspection table 21 is provided as shown in FIG. 2, and the holding part 22, the light supply part 30, etc. which hold the 1st and 2nd collimator 10b are mounted. On the other hand, although not shown, a movable wheel can be provided at the lower end of the inspection table 21. Thus, the collimator inspection apparatus 20 according to the present invention can be easily moved to a predetermined inspection position. In this case, it would be advantageous to separately provide a brake device on the rolling wheels to prevent the inspection device 20 moved to a predetermined inspection position from moving arbitrarily.

As shown in FIG. 2, the grip portion 22 is disposed coaxially with a first spacing between the first collimator 10a and the first collimator 10a having a pair of fibers 13a and 13b. The second collimator 10b is gripped from the side. In the lateral area of the gripping portion 22, an optical supply unit 30 for transmitting an optical signal to the first collimator 10a and a first light receiving unit 40 for receiving the optical signal are provided.

As shown in FIG. 2, the light supply unit 30 is connected to one fiber 13a of the first collimator 10a. Accordingly, the light supply unit 30 generates an optical signal and transmits the light signal to one fiber 13a of the first collimator 10a connected to the light supply unit 30. In addition, the light supply unit 30 is electrically connected to the meter 50 to be described later, and transmits the optical signal value transmitted to one fiber 13a of the first collimator 10a to the meter 50.

As shown in FIG. 2, the first light receiving unit 40 is connected to the fiber 13A of the second collimator 10b. In addition, the first light receiving unit 40 is electrically connected to the meter 50 to be described later. Accordingly, the first light receiving unit 40 passes through the pigtail and the green lens that the optical signal incident on one side of the fiber 13a of the first collimator 10a forms the first collimator 10a, and thus, of the second collimator 10b. The value transmitted to the fiber 13A is received, and the received optical signal value is transmitted to the measuring instrument 50.

As shown in the block diagram of FIG. 3, the measuring instrument 50 is electrically connected to the light supply unit 30 and the first light receiving unit 40 so as to be connected to the first light receiving unit 40 and the first light receiving unit 40. The optical signal value incident to the collimator 10a and the optical signal value transmitted to the second collimator 10b through the first collimator 10a are received. Accordingly, the measuring instrument 50 calculates the optical signal values, measures the Transmitted Insertion Loss, which is one of optical characteristics when the first and second collimators 10a and 10b are used as a package, and then measures the examination table 21. Output through the image display unit 60 provided on the.

Referring to the operation of the collimator inspection apparatus 20 according to the present invention by such a configuration as follows.

In order to measure the optical characteristics (Transmitted Insertion Loss) when the first and second collimators 10a and 10b are used as a package, first and the first and second objects to be inspected in the holding part 22 provided on the inspection table 21. 2 Install the collimators 10a and 10b. At this time, it is preferable that the holding part 22 is provided with a predetermined stopper (not shown) for preventing the holding positions of the first and second collimators 10a and 10b from changing each time.

After holding the first and second collimators 10a and 10b on the gripper 22, the one side fiber 13a of the first collimator 10a and the light supply unit 30 are connected. The fiber 13A of the second collimator 10b is connected to the first light receiving unit 40.

When the connection of the light supply unit 30 and the first light receiver 40 to the fibers 13a and 13A of the first and second collimators 10a and 10b is completed, the first collimator 10a through the light supply unit 30 is completed. The optical signal is transmitted to one side of the fiber (13a). Accordingly, the optical signal incident on one side of the fiber 13a of the first collimator 10a passes through the pigtail and the green lens forming the first collimator 10a and the fiber 13A of the second collimator 10b provided thereon. ) And is received by the first light receiving unit 40 connected to the fiber 13A of the second collimator 10b.

Accordingly, the measuring device 50 electrically connected to the light supply unit 30 and the first light receiving unit 40 respectively has an optical signal value incident on one side of the fiber 13a of the first collimator 10a and a first collimator ( Receive the value transmitted to the fiber 13A of the second collimator 10b through 10a), calculate the Transmitted Insertion Loss when the first and second collimators 10a and 10b are used as a package, and calculate the calculated value. Output through the image display unit 60.

In addition, when the collimator inspection apparatus 20 according to the present invention, as shown in Figure 4, further comprises a second light receiving portion 41 connected to the other fiber 13b of the first collimator (10a), Reflected insertion loss, which is one of optical characteristics of one collimator 10a, can also be measured. Here, as shown in FIG. 4, the second light receiver 41 is provided at one side of the test table 21 and connected to the other fiber 13b of the first collimator 10a.

According to this configuration, in order to measure Reflected Insertion Loss, which is one of optical characteristics of the first collimator 10a, in the collimator inspection apparatus 20 according to the present invention, first, the grip part 22 provided on the inspection table 21 is provided. The first and second collimators 10a and 10b of the inspection target are mounted. After holding the first and second collimators 10a and 10b in the holding unit 22, the light supply unit 30 is connected to one fiber 13a of the first collimator 10a, and the first collimator ( The other fiber 13b of 10a connects the second light receiver 41.

When the connection between the light supply unit 30 and the second light receiver 41 to both fibers 13a and 13b of the first collimator 10a is completed, the light supply unit 30 is connected to the first collimator through one fiber 13a. The optical signal is transmitted to 10a. Accordingly, the optical signal incident on one side of the fiber 13a of the first collimator 10a passes through the pigtail and the green lens forming the first collimator 10a and the second collimator 10 disposed above the first collimator 10a. 10b). Here, the second collimator 10b totally reflects the optical signal received from the first collimator 10a and returns it to the second light receiving unit 40 through the other fiber 13b of the first collimator 10a.

Accordingly, the measuring device 50 connected to the light supply unit 30 and the second light receiving unit 41 respectively enters the optical signal value incident on one fiber 13a of the first collimator 10a and the other fiber 13b. In response to the returned value, the Reflected Insertion Loss, which is an optical characteristic of the first collimator 10a, is calculated, and the calculated value is output through the image display unit 60. For example, an optical signal of 100 db is supplied from the light supply unit 30 to one side of the fiber 13a, and an optical signal incident through the one side of the fiber 13a is totally reflected by the second collimator 10b to form the other side of the fiber 13b. If 98 db is returned to the second light receiving unit 41 through, the meter 50 subtracts two and outputs 2 db as the reflected insertion loss of the first collimator 10a through the image display unit 60. (See Figure 5). Therefore, the operator can determine whether the reflected insertion loss of the first collimator 10a is based on the value output through the image display unit 60.

In addition, in the collimator inspection apparatus 20 according to the present invention, as shown in Figure 6, when further comprising a non-polarization supply unit 31 coupled to one side fiber 13a of the first collimator (10a), the first Polarization dependent loss, which is one of optical characteristics when the collimator 10a and the second collimator 10b are used as a package, may also be measured. Here, the polarized light supply unit 31 is provided on one side of the inspection table 21, as shown in Figure 5, coupled to one side of the fiber 13a of the first collimator (10a) is not attached to the first collimator (10a) Delivers polarized light signals. Thus, the unpolarized optical signal transmitted to one side fiber 13a of the first collimator 10a is received by the fiber 13A of the second collimator 10b provided on the upper part via the first collimator 10a and the first light receiver Is passed to 40.

According to this configuration, in order to measure Polarization Dependent Loss, which is one of optical characteristics when the first collimator 10a and the second collimator 10b are used as a package in the collimator inspection apparatus 20 according to the present invention, the inspection The first and second collimators 10a and 10b to be inspected are mounted on the grip portion 22 provided on the table 21. After holding the first and second collimators 10a and 10b in the gripping portion 22, the non-polarization supply portion 31 is connected to one side fiber 13a of the first collimator 10a, and the second collimator The fiber 13A of 10b is connected to the first light receiver 40.

When the connection of the unpolarized light supply unit 31 and the first light receiver 40 to the fibers 13a and 13A of the first and second collimators 10a and 10b is completed, the first collimator through the non-polarized light supply unit 31 is completed. The polarizing signal is transmitted to one side fiber 13a of 10a. Accordingly, the unpolarized signal incident on one side of the fiber 13a of the first collimator 10a passes through the pigtail and the green lens forming the first collimator 10a and the fiber of the second collimator 10b provided thereon. 13A) is received by the first light receiving unit 40 connected to the fiber 13A of the second collimator 10b.

Accordingly, the meter 50 receives the optical signal value from the first light receiving unit 40 and calculates the polarization dependent loss when the first and second collimators 10a and 10b are used as a package, and calculates the calculated value. It outputs through the image display part 60 (refer FIG. 7).

As described above, according to the present invention, there is provided a collimator characteristic inspection apparatus which can increase the reliability of the product by partially inspecting the collimator.

Claims (6)

A first collimator having a pair of fibers; A second collimator disposed coaxially with a predetermined distance from the first collimator and having a single fiber; An examination table; A holding part provided on the inspection table to hold the first and second collimators of the inspection object; An optical supply unit configured to be coupled to one fiber of the first collimator to transmit a predetermined optical signal; A first optical receiver coupled to a fiber of the second collimator to receive a value transmitted to the fiber of the second collimator by an optical signal incident to the first collimator; A measuring unit for calculating an optical signal value incident to the first collimator and a value returned to the second collimator; And a video display unit for displaying the measuring instrument value. The method of claim 1, And the measuring unit calculates a Transmitted Insertion Loss by subtracting an optical signal value incident to one fiber of the first collimator and a value transmitted to the fiber of the second collimator. The method of claim 1, And a second light receiving unit coupled to the other fiber of the first collimator. The method of claim 3, The measuring unit calculates Reflected Insertion Loss by subtracting an optical signal value incident to one fiber of the first collimator and a value returned to the other fiber of the first collimator after total reflection by the second collimator. Collimator characteristic inspection device. The method of claim 1, And a non-polarization supply unit provided to be coupled to one side of the first collimator to transmit a predetermined non-polarization optical signal to the first collimator. The method of claim 5, And the measuring device measures a polarization dependent loss of the unpolarized signal supplied from the unpolarized supply to the first light receiver through the first and second collimators.