JP2000241294A - Method and equipment for measuring optical output characteristics of ld module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To measure the optical output of a laser diode module while suppressing return light thereto. SOLUTION: In the method for measuring the optical output characteristics for the drive current of a laser diode module 1 being outputted to a single mode optical fiber 2 and the differentiation characteristics of optical output, laser light from the single mode optical fiber 2 is received by a measuring optical fiber 4 having a diameter larger than that of the core of the single mode optical fiber 2, the light returning from the measuring optical fiber 4 side to the laser diode module 1 is extinguished and then the optical output characteristics for the drive current of the laser diode module 1 and the differentiation characteristics of optical output are measured based on the laser light being outputted through the measuring optical fiber 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for measuring an optical output characteristic of an LD module for measuring an optical output characteristic with respect to a drive current of a laser diode (LD) module and a differential characteristic of the optical output.

[0002]

2. Description of the Related Art A method and an apparatus for measuring an optical output characteristic of an LD module for measuring an optical output characteristic with respect to a drive current of the LD module and a differential characteristic of the optical output have been developed. FIG. 4 shows a method for measuring the light output characteristics of an LD module according to a conventional example.
This will be described with reference to FIG.

In FIG. 4, an LD module 1 has a single mode optical fiber (hereinafter referred to as SM) having a small diameter core.
2).

[0004] The tip of the SMF 2 is processed with an optical connector, and is provided with a spherically polished ferrule 3.

[0005] The ferrule 3 is disposed directly toward the power sensor 7 a of the optical power meter 7.

The optical power meter 7 receives a laser beam emitted from the ferrule 3 through a space with a power sensor 7a, and measures the optical output of the LD module 1 with a main body 7b.

[0007]

However, the method for measuring the optical output characteristics of an LD module according to the above-described conventional example has the following problems.

When the LD module 1 is driven by the LD driver 9 based on the output of the controller 10, when the laser light is emitted from the end face of the ferrule 3 into the space, due to the difference in the refractive index between the fiber and the air, about -14 dB. Reflects and produces return light.

When the return light reaches the active layer of the LD chip, the light emission state of the laser is disturbed. In particular, the differential characteristic of the light output fluctuates, and a measurement result with good reproducibility cannot be obtained. Therefore, there is a problem that the quality of the LD module cannot be correctly determined.

Although it is possible to prevent return light by incorporating an isolator in the LD module itself, it is not advisable because the cost increases.

In order to avoid this problem, another second method is used. The second method will be described with reference to FIG.

In FIG. 5, the SMF of the LD module 1
2, a measurement optical fiber 13 having a small-diameter core is coupled via an optical connector coupling section 6. The optical connector coupling section 6 includes ferrules 3 and 5 and a split sleeve 8.

In this case, since the laser light of the LD module 1 is output by the single mode optical fiber 2, a single mode fiber having a small diameter core is usually used as the measuring optical fiber 13.

The optical connector coupling portion 6 has a structure in which the ferrules 3 and 5 of the opposing optical fibers are brought into contact with each other and an air layer is not interposed between the optical fiber coupling portions. Become.

From the optical connector coupling section 6 to the optical power meter 7
If the generation of the return light is suppressed between (for example, the isolator 1
4 and the output end to the optical power meter 7 is obliquely cut, etc.) to solve the problem of the return light.

However, the optical connector connection between the single mode fibers according to the second method has a large coupling loss, and the measured value is a value including the coupling loss.

If the coupling loss is a fixed value, the influence of the connection loss can be avoided by correcting the measured value. However, the cause of the connection loss is a fiber located at the center of the ferrules 3 and 5. Because of the eccentricity of the core, the connection loss value differs depending on the combination of the ferrules 3 and 5.
Correction is not possible.

Therefore, when measuring the optical output characteristics with high precision, the measurement is performed by combining the above two methods.

Specifically, the power value measured by the first method is used as a reference value for performing the second measurement,
The method is adapted to measure the light output characteristic and the differential characteristic of the LD module by the above method.

As described above, by combining the first method and the second method, high-precision measurement can be performed. However, this method requires two measurements, thereby reducing work efficiency. There is a problem of bad.

An object of the present invention is to provide a method and an apparatus for measuring the characteristics of an LD module which can measure the optical output of the LD module without coupling loss while suppressing the return light to the LD module.

[0022]

In order to achieve the above object, a method for measuring characteristics of an LD module according to the present invention is directed to an optical output characteristic with respect to a drive current of a laser diode module output from a laser diode module to a single mode optical fiber. And L for measuring the differential characteristic of light output
A method for measuring an optical output characteristic of a D module, comprising: receiving a laser beam from the single mode optical fiber on a measurement optical fiber having a core having a larger diameter than a core of the single mode optical fiber; From the side to return light to the laser diode module side,
A light output characteristic and a light output differential characteristic with respect to a drive current of the laser diode module are measured based on the laser light output through the measurement optical fiber.

Further, the optical output characteristic measuring device for an LD module according to the present invention has a measuring optical fiber and a return light extinction section, and drives the laser diode module output from the laser diode module to the single mode optical fiber. An optical output characteristic measuring device for an LD module for measuring an optical output characteristic with respect to a current and a differential characteristic of an optical output, wherein the measuring optical fiber is a fiber having a core having a larger diameter than a core of the single mode optical fiber. And the laser beam from the single mode optical fiber is received and output, and the return light disappearance section is for eliminating return light from the measurement optical fiber side to the laser diode module side.

Further, the tip of the ferrule attached to the single mode optical fiber and the measuring optical fiber is spherically polished so that the ferrule is brought into close contact with the optical connector coupling portion.

Further, the end face on the output side of the measuring optical fiber is cut obliquely with respect to the optical axis to eliminate the return light from the measuring optical fiber side to the laser diode module side.

Further, by inserting an optical isolator into the optical fiber for measurement, return light from the optical fiber for measurement to the laser diode module side is eliminated.

[0027]

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

FIG. 1 is a block diagram showing an apparatus for measuring characteristics of an LD module according to an embodiment of the present invention.

FIG. 1 shows an LD according to an embodiment of the present invention.
In the module characteristic measuring device, the L
An optical fiber for measurement 4 is optically coupled to a single mode optical fiber (hereinafter, referred to as SMF) 2 having a small diameter core 11 attached to the D module 1 by an optical fiber coupling section 6.

Here, the measuring optical fiber 4 uses a multimode fiber (hereinafter, referred to as MMF) having a core 12 having a larger diameter than the single mode optical fiber 2.

The MMF 4 has an end opposite to the end to which the SMF 2 is connected facing the power sensor 7a of the optical power meter 7.

The ferrule 3 attached to the output end of the SMF 2 and the ferrule 5 attached to the input end of the MMF 4 are both spherically polished and inserted into the split sleeve 8 of the optical connector coupling portion 6 from the opposite end. The spherically polished tips of the ferrules 3 and 5 are in close contact in the split sleeve 8. The spherically polished tips of the two ferrules 3 and 5 are in close contact in the split sleeve 8, so that laser light is not emitted to the space, and optical coupling loss is almost eliminated.

The output end 4a of the MMF 4 toward the power sensor 7a of the optical power meter 7 has a structure in which the end face is cut obliquely with respect to the optical axis so that reflection such as going backward in the fiber does not occur. Has become.

FIG. 1 shows an LD according to an embodiment of the present invention.
In the module characteristic measuring device, the controller 10
When the LD module 9 is driven by the LD driver 9 on the basis of the output of the optical power meter 7, the laser light is introduced into the MMF 4 via the optical connector coupling section 6, is irradiated on the power sensor 7a of the optical power meter 7, and the light intensity is reduced by the main body 7b. Measured.

The controller 10 automatically controls the LD driver 9 and the optical power meter 7, sweeps the drive current of the LD driver 9, and outputs the light output characteristics and light as shown in FIGS. 2 (a) and 2 (b). An output differential characteristic is obtained.

The method of measuring the optical output differential characteristic is a method of obtaining the ratio of the increase of the optical output with respect to the sweep step of the drive current (difference method), or a method in which a small AC signal is superimposed on the drive current. There is a method (AC superposition method) of detecting and measuring the AC component appearing in (1) and calculating the ratio thereof, and the measurement is performed using these methods.

FIG. 3 is a sectional view showing details of the optical connector coupling section shown in FIG. In the figure, the ferrule 3 and the ferrule 5 are inserted into the split sleeve 8 so as to face each other, and the ends come into contact near the center in the split sleeve 8, so that the core 11 of the SMF 2 and the core 12 of the MMF 4 are joined. I have.

Since the core 11 and the core 12 are in close contact with each other in the split sleeve 8 and have substantially the same refractive index, the laser light entering through the core 11 hardly reflects at the contact interface between the core 11 and the core 12. , And enters the core 12.

The amount of reflection depends on the polished state of both contact surfaces. However, in a polished state called SPC polishing, the amount of reflection is suppressed to -40 dB or less. SPC polishing is introduced in catalogs of Seiko Instruments Inc. and the like.

The core 11 of the SMF 2 has a core diameter of about 9 μm, the core 12 of the MMF 4 has a core diameter of 50 μm,
Even if both cores 11 and 12 are eccentric, if the amount of eccentricity is within the standard, the coupling loss is about 0.01 dB and poses no problem.

In the above embodiment, the MMF is used as the measuring optical fiber. However, a step index type fiber (core diameter 200 μm or the like) having a larger diameter core than the MMF may be used.

The reflection from the measuring device can be prevented not only by obliquely cutting the end face of the measuring optical fiber but also by inserting an optical isolator into the measuring optical fiber.

[0043]

As described above, according to the present invention, L
By introducing the optical output of the D module into the measurement optical fiber having a large core diameter, the laser term is not emitted into space, and
Since there is no difference in the refractive index between the single mode optical fiber of the LD module and the optical fiber for measurement, it is possible to prevent return light generated at the fiber end face of the LD module, to cause almost no coupling loss, and to reduce the light output. Can be measured with high accuracy, and the differential characteristics of the light output can be measured stably.

Further, since the light output and the differential characteristics can be measured in the same process, work efficiency can be improved and automation can be performed.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing an apparatus for measuring characteristics of an LD module according to an embodiment of the present invention.

FIG. 2 is a characteristic diagram showing light output characteristics and light output differential characteristics.

FIG. 3 is a sectional view showing details of an optical connector coupling section shown in FIG. 1;

FIG. 4 is a configuration diagram showing an apparatus for measuring characteristics of an LD module according to a conventional example.

FIG. 5 is a configuration diagram showing an apparatus for measuring characteristics of an LD module according to a conventional example.

[Explanation of symbols]

 1 LD module 2 Single mode optical fiber 4 Measurement optical fiber

Claims (5)

[Claims] 1. A method for measuring an optical output characteristic of an LD module for measuring an optical output characteristic and a differential characteristic of an optical output with respect to a drive current of a laser diode module output from a laser diode module to a single mode optical fiber, wherein: The laser light from the mode optical fiber is received by the measuring optical fiber having a core larger in diameter than the core of the single mode optical fiber, and the return light from the measuring optical fiber side to the laser diode module is eliminated. An optical output characteristic measuring method for an LD module, comprising measuring an optical output characteristic and an optical output differential characteristic with respect to a drive current of the laser diode module based on a laser beam output through the measuring optical fiber. 2. A method for measuring a light output characteristic and a differential characteristic of a light output with respect to a drive current of a laser diode module output from a laser diode module to a single mode optical fiber, the optical fiber having a measurement optical fiber and a return light disappearance part. An optical output characteristic measuring device for an LD module, wherein the measuring optical fiber is a fiber having a core having a larger diameter than a core of the single mode optical fiber, and receives laser light from the single mode optical fiber. An optical output characteristic measuring device for an LD module, wherein the return light extinction section eliminates return light from the measurement optical fiber side to the laser diode module side. 3. The LD according to claim 2, wherein the tip of the ferrule attached to the single mode optical fiber and the measuring optical fiber is spherically polished and brought into close contact in an optical connector coupling portion. Optical output characteristics measuring device for modules. 4. An output end face of the measuring optical fiber is cut obliquely with respect to an optical axis to eliminate return light from the measuring optical fiber side to the laser diode module side. L according to claim 2, characterized in that:
Optical output characteristic measuring device for D module. 5. The optical fiber according to claim 2, wherein an optical isolator is inserted into the optical fiber for measurement so that return light from the optical fiber for measurement to the laser diode module is eliminated. 3. The optical output characteristic measuring device for an LD module according to claim 1.