KR100243662B1 - Apparatus for measuring optic energy at both sides of laser diode - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

Bi-directional optical energy measuring device of laser diode

2. The technical gist of the invention

The present invention is a path for absorbing the light energy emitted from the measurement object, the crystal rod is in close contact with both sides of the laser diode, it is easy to measure the bi-directional light energy generated from the laser diode at the same time bidirectional light of the laser diode The purpose is to provide an energy output device.

3. Summary of Solution to Invention

The present invention is fixed to the laser diode, the laser diode support means is formed hole;

An electrode plate to which power is applied; A crystal rod fitted into each of the through-holes of the laser diode supporting means, the crystal rod providing a path through which the center of each end surface is located close to the laser diode to absorb and move light energy emitted from the laser diode; And a photodiode for receiving optical energy output from both crystal rods.

4. Important uses of the invention

The present invention is applied to the optical energy measuring device of the laser diode.

Description

Two-way optical energy measuring device of laser diode {APPARATUS FOR MEASURING OPTIC ENERGY AT BOTH SIDES OF LASER DIODE}

The present invention relates to a two-way optical energy measuring device of a laser diode using a crystal rod, in particular to prevent damage to the surface of the laser diode during the measurement of the light energy to improve its production yield, divergent from both sides of the laser diode The present invention relates to a laser diode bidirectional optical energy measuring device which minimizes measurement time by simultaneously measuring the optical energy.

In general, in order to complete a high speed optical communication laser diode as an optical module, a multi-stage test and assembly process is required. In this case, the cost of professional design and precision processing equipment required for the manufacture of expensive optical components and optical modules is greatly increased. It is becoming. Therefore, in order to prevent the defect of the optical module generated by using the defective laser diode, it is necessary to carefully select the laser diode before the assembly process of the optical module, which is achieved through the process of measuring the optical energy of the laser diode.

In this optical communication laser diode, optical energy is emitted in both front and rear directions, and the optical energy at the front side is transmitted to the optical fiber as an optical communication signal, and the optical energy at the rear side is measured using a monitoring photodiode. Since the light energy of the front side is adjusted according to the light energy of the rear side, it is required to measure the bidirectional light energy of the laser diode for optical communication.

1A to 1C, various embodiments of an optical energy measuring apparatus of a laser diode according to the prior art will be described as follows.

As shown in FIG. 1A, a first embodiment of an optical energy measuring apparatus of a laser diode according to the prior art includes a housing 1 having a shape of a box body having an opening formed at an upper side thereof, and a housing such that one end thereof protrudes outward. An optical fiber 2 mounted through one side of (1), a plurality of electrical components 3 mounted on opposite sides of the housing 1 to receive an external power source, and the optical fiber 2 A laser diode 10 mounted on the other end side and fixed to the inside of the housing 1 and connected to the electrical component 3 by a metal wire bonding method to oscillate by receiving external power, and one end of the optical fiber 2. It was made in the form of a partially finished product of an optical module with a photo detector 4 located at the side.

In the optical energy measuring apparatus of the laser diode according to the first embodiment, when the laser diode 10 is oscillated by receiving power from the outside through the electric component 3, one side of the laser diode 10 is provided. The light energy generated from was measured in the photodetector 4 through the optical fiber 2.

In addition, as shown in FIG. 1B, the second embodiment of the optical energy measuring apparatus of the laser diode according to the prior art includes a main body 5 having a disc shape of a unit package formed to receive external power, and a laser. A projection 6 formed to protrude on one side of the main body 5 so that the diode 10 can be mounted on the upper side thereof, and the light energy positioned on one side of the laser diode 10 and emitted from the laser diode 10. It includes a photodetector (not shown) for measuring the.

Here, the laser diode 10 is fixed to the upper surface of the protrusion 6 by using a conductive metal joint, for example, silver epoxy so as to emit light by receiving an external power source, the metal wire to the main body 5 It was connected by the bonding 11 method.

In the laser diode optical energy measuring apparatus according to the second embodiment, when the laser diode 10 is oscillated by receiving power from the outside through a unit package, the light emitted from one side of the laser diode 10 is emitted. The energy was measured by the photodetector. In order to measure the light energy emitted from the other side of the laser diode 10, the laser diode 10 is detached from the unit package and then fixed again so that the other side is positioned at the photodetector side. By measuring the light energy emitted from the other side of the laser diode (10).

As shown in FIG. 1C, a third embodiment of the laser diode optical energy measuring apparatus according to the related art is provided such that a laser diode 10 is mounted on an upper side thereof and an external power source can be applied to the laser diode 10. A pedestal 7 made of a conductive material, a fixing member 8 made of a triangular conductive material and pressed against the pedestal 7 by pressing the laser diode 10 mounted on the pedestal 7, and the laser diode ( 10) includes a photodetector (not shown) mounted on one side.

Here, the pedestal 7 and the fixing member 8 are formed with screw holes 7a and 8a for fastening screws for fixing the fixing member 8 to the pedestal 7, respectively.

In the laser diode optical energy measuring apparatus according to the third embodiment of the prior art, the laser diode 10 is placed on a predetermined portion of the upper surface of the pedestal 7 and then fixed to contact the upper surface of the laser diode 10. The member 8 is positioned, and the screw hole 7a of the pedestal 7 is aligned with the screw hole 8a of the fixing member 8, and then the screw is tightened to press the laser diode 10 to press the pedestal. In close contact with (7). Subsequently, the laser diode 10 was oscillated by applying power from the outside, and the light energy emitted from one side of the laser diode 10 was measured through a photodetector.

In order to measure the light energy emitted from the other side of the laser diode 10, the fixing member 8 is detached from the pedestal 7, and the other side of the laser diode 10 is the photodetector side. By being positioned at and then repeating the above manner, the bidirectional light energy of the laser diode 10 was measured.

However, the laser diode optical energy measuring apparatus according to the first, second and third embodiments as described above has the following problems, respectively.

That is, in the optical energy measuring apparatus of the laser diode according to the first embodiment, when the characteristics of the laser diode 10 do not meet the specifications, the production cost is increased because the entire part of the assembled optical module must be discarded. Since the measuring device must be newly assembled according to the shape of the optical module and the partially finished product, there is a problem that the work becomes complicated.

The optical energy measuring apparatus of the laser diode according to the second embodiment, in order to use the laser diode 10 passed in the measurement, it is necessary to break the metal wire bonding 11 and remove the adhesive surface after the measurement, There is a problem in that the entire laser diode 10 is broken or a surface thereof is damaged.

In addition, due to the complicated preparation process and the difficulty of assembly and disassembly, there are other problems in not only reducing the manufacturing yield of the laser diode 10 but also increasing the manufacturing cost.

In the optical energy measuring device of the laser diode according to the third embodiment, the laser diode 10 may be damaged by the force of the fixing member 8, and the fixing member 8 may be a laser diode. Since it is located above (10), there is a problem that it is difficult to grasp the exact position of the laser diode (10).

In addition, the optical energy measuring device of the laser diode according to the prior art of the first, second and third embodiments as described above, the laser diode of at least two times to measure the light energy generated on both sides of the laser diode. Since the detachment process must be repeated, the laser diode is damaged and manufacturing yield is reduced, and there is a common problem that it is difficult to compare the bidirectional light energy under the same conditions.

Therefore, the present invention has been devised in view of the above problems, and as a path for absorbing light energy emitted from a measurement object, a pair of crystal rods are brought into close contact with both sides of a laser diode, and the outside of each crystal rod By providing photodiodes for measuring the optical energy due to the oscillation of the laser diode at the end, the laser diode can not only measure the bidirectional optical energy generated from the laser diode at the same time but also have reliability in accuracy. Its purpose is to provide a two-way optical energy measuring device.

1a to 1c are first, second and third embodiment of the optical energy measuring apparatus of the laser diode according to the prior art.

Figure 2 is an exploded perspective view showing an embodiment configuration of a bidirectional optical energy measuring device of a laser diode using a crystal rod according to the present invention.

Figure 3 is an assembled perspective view of the bidirectional optical energy measuring device of the laser diode according to the present invention.

4 is a detailed view showing part A of FIG.

* Explanation of symbols for the main parts of the drawings

10: laser diode 20a, 20b: first and second crystal rods

30: support means 30a, 30b: first and second conductors

31a, 31b: Insertion hole 32a, 32b: Adjustment screw hole

40: electrode auxiliary support 40a: metal plate

41: wire 42: first fixing threaded hole

50: support means 51: support

52: protrusion 52a: first crystal rod groove

52b: 1st integrated screw hole 53: 2nd fixed screw hole

54: block 54a: second crystal rod groove

54b: second integrated screw hole 60a, 60b: first and second photodiodes

In order to achieve the above object, the present invention, a laser diode support means for pressing and fixing the laser diode to be measured, the through-holes are formed respectively adjacent to both sides of the fixed laser diode; Power supply means for applying external power to the laser diode support means; Optical path providing means which is inserted into and supported in both through-holes of the laser diode supporting means, the center of each end face being positioned proximate to the laser diode to provide a movement path of optical energy emitted from the laser diode; And a light receiving means for receiving the light energy output from the light path providing means on both sides.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 2 to 4 as follows.

As shown in FIG. 2, the bidirectional optical energy measuring apparatus of the laser diode according to the present invention provides a movement path of light emitted from the laser diode 10 in close contact with both sides of the laser diode 10 used for optical communication. The first and second crystal rods 20a and 20b and the laser diode 10 are supported, and the first and second crystal rods 20a and 20b are supported to be in close contact with both sides of the laser diode 10. The support means 30 made of a conductive material and a plurality of metal plates 40a which are located on the lower surface of the support means 30 and receive power from the outside and transmit the power to the support means 30 are maintained at predetermined intervals. An electrode auxiliary support 40, the support means 30 and the electrode auxiliary support 40 is mounted and the support means 50 for dissipating heat due to the oscillation of the laser diode 10, and the first and first 2 Delivery through crystal rods 20a and 20b The first and second photodiodes 60a and 60b respectively measure optical energy of the laser diode 10.

The support means 30 is composed of first and second conductors 30a and 30b separated from each other.

The first and second conductors 30a and 30b each have an upright portion provided to face each other with flat surfaces formed so as to support the laser diode 10 in close up and down directions. Crystal rods 20a and 20b respectively have upright portions formed with insertion holes 31a and 31b formed to be positioned on both sides of the laser diode 10, respectively. In addition, an adjustment screw hole 32a to which one side of the first and second conductors 30a and 30b is coupled to adjust screws for pressing the first and second crystal rods 20a and 20b to fix their positions. , 32b) are formed respectively. In this case, portions of the first and second crystal rods 20a and 20b protrude from both ends of the support means 30.

A wire 41 for applying an external power source to the metal plate 40a is connected to the electrode auxiliary support 40, and fixing screws for fixing it to the support means 50 on both sides of the electrode auxiliary support 40. A first fixing screw hole 42 to be fastened is formed.

In addition, the electrode auxiliary support 40 has a structure in which a conductive material is coated only on an upper surface thereof to electrically insulate the support means 50.

Protruding portions 52 formed in a substantially rectangular parallelepiped shape formed to protrude upwardly are formed at both side portions of the supporting means 50, and communicate with the first fixing screw hole 42 between the two protruding portions 52. A pedestal 51 having a second fixing screw hole 53 is formed, and a pair of blocks 54 fixed to the upper side of each of the protrusions 52.

Here, the semi-circular first crystal rod grooves 52a for positioning portions of the first and second crystal rods 20a and 20b protruding from both ends of the support means 30 are formed on the upper surfaces of the two protrusions 52. A first integration screw hole 52b is formed to which the integrated screw is fastened to fix the block 54.

In addition, a second crystal rod groove 54a is formed below the two blocks 54 to accommodate the first and second crystal rods 20a and 20b, respectively, in combination with the first crystal rod groove 52a. Then, second integration threaded holes 54b communicating with the respective first integration threaded holes 52b are formed.

Such assembling state of the bidirectional optical energy measuring device of the laser diode according to the present invention will be described with reference to FIG.

After the first fixing screw hole 42 of the electrode auxiliary support 40 is aligned with the second fixing screw hole 53 of the pedestal 51, the fixing screw is fastened to attach the electrode auxiliary support 40 to the pedestal 51. ) Firmly. The laser diode 10 is positioned between the first and second conductors 30a and 30b, and then the first and second conductors 30a and 30b are brought into close contact with each other to support the laser diode 10. First and second crystal rods 20a and 20b are inserted through respective insertion holes 31a and 31b such that one ends of the first and second crystal rods 20a and 20b are in close contact with both sides of the laser diode 10. Then, the adjustment screw is fastened to fix the first and second fixation rods 20a and 20b.

Next, the support means 30 is positioned on the metal plate 40a of the electrode auxiliary support 40, and at the same time, the first and second crystal rods 20a and 20b protrude from both ends of the support means 30. To the first crystal rod groove (52a) on the projection (52). Then, the second crystal rod groove 54a of the block 54 is coupled to the first crystal rod groove 52a, and the first and second integrated threaded holes of the protrusion 52 and the block 54 ( 52b, 54b) and tighten the integrated screw.

The first and second photodiodes 60a and 60b for measuring light energy are respectively positioned at both ends of the first and second crystal rods 20a and 20b protruding to both sides of the supporting means 50. The measuring apparatus of the present invention as shown in Fig. 3 is completed.

Referring to Figures 3 and 4 will be described the operation of the laser diode bidirectional optical energy measuring device as follows.

When power is supplied to the electrode auxiliary support 40 from an external power source, power is applied to the laser diode 10 through the support means 30 to oscillate. At this time, the emitted light is transmitted to the first and second photodiodes 60a and 60b along the first and second crystal rods 20a and 20b, thereby measuring bidirectional optical energy of the laser diode 10.

As described above, an apparatus for measuring bidirectional optical energy of a laser diode using a crystal rod according to the present invention includes first and second crystal rods 20a and 20b that absorb light energy of the laser diode 10 and the respective crystal rods ( Since the first and second photodiodes 60a and 60b for receiving the light energy of the laser diode 10 through 20a and 20b are positioned at both sides of the laser diode 10, the bidirectional light of the laser diode 10 is provided. In addition to measuring the energy simultaneously, it is also possible to repeat the test of multiple laser diodes using one device made in accordance with the present invention.

The present invention described above is not limited to the above-described embodiments and drawings, and various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those who have

In the laser diode bidirectional optical energy measuring device according to the present invention as described above, the crystal rods are installed on both sides of the laser diode, so that it is easy to measure the light output measurement position of both sides by mounting a single laser diode chip. It is possible to compare the measurement of laser diode light output under the same conditions. It is possible to easily pull out the electrode required to drive the laser diode using the metal plate and the laser diode support means. Since the surface damage is minimized, the surface damage of the laser diode can be minimized even after the bidirectional optical output measurement and various characteristic tests using the measuring device of the present invention, and the stable optical properties can be obtained.

Claims (7)

A laser diode support means for pressing and fixing a laser diode as a measurement object, each through hole being formed adjacent to both sides of the fixed laser diode; Power supply means for applying external power to the laser diode support means; Optical path providing means which is inserted into and supported in both through-holes of the laser diode supporting means, the center of each end face being positioned proximate to the laser diode to provide a movement path of optical energy emitted from the laser diode; And Light receiving means for receiving the light energy output from the light path providing means on both sides Bidirectional optical energy measuring device of a laser diode comprising a. The method of claim 1, Apparatus for measuring bidirectional optical energy of a laser diode, wherein the optical path providing means includes first and second crystal bars. The method of claim 2, The light receiving means, A first photodiode for receiving light energy moved along the first crystal rod; Laser diode bi-directional optical energy measuring device including a second photodiode for receiving the light energy moved along the second crystal rod. The method of claim 1, Bidirectional optical energy measuring device of a laser diode, characterized in that the laser diode support means is formed of a conductive material. The method of claim 1, The power supply means is a two-way optical energy measuring device of a laser diode, characterized in that only the upper surface is coated with a conductive material. The method according to claim 1 or 5, The power supply means is disposed in the upper central portion, the bidirectional optical energy measuring device of the laser diode further comprises a support means for supporting the first and second crystal rods respectively on both sides. The method of claim 6, And said receiving means is electrically insulated from said power supply means.

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