KR100406862B1 - Apparatus and method for measuring reflectivity of optical fiber reflector - Google Patents

Abstract

PURPOSE: An apparatus and a method for measuring reflectivity of an optical fiber reflector are provided to reduce a measuring error and measure accurately the reflectivity by using a circulator as well as a coupler. CONSTITUTION: A loss characteristic is obtained according to a waveform of a circulator(210). The loss characteristic is obtained according to a coupler and the waveform of the circulator(210). An output port of the circulator is connected to an optical fiber reflector(220). The power of the output beam of the second input port of the circulator and the power of the output beam of the second output port of the coupler are measured by using a power meter(230). The intensity of the corrected reflection beam to a power variation of an input light source is measured according to a variation of waveform. The measured value is corrected by using the loss characteristic and the reflectivity of an optical reflector is calculated.

Description

Apparatus and method for measuring reflectivity of optical fiber reflector

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reflectance measurement window and method of an optical fiber amplifier, and more particularly, to an apparatus for measuring reflectance of an optical fiber reflector for measuring the wavelength dependence of the optical fiber reflector more quickly and reliably.

In order to construct a recycled erbium doped fiber amplifier (REDFA), an optical fiber reflector capable of reflecting signal light or pump light is required. In order to increase the efficiency of the REDFA, a design suitable for the characteristics according to the use of an erbium-doped fiber amplifier (EDFA) is required. In this case, it is essential to measure reflectance according to the wavelength of the optical fiber reflector.

1 is a block diagram of an apparatus for measuring a reflectance of a conventional optical fiber reflector. In general, in order to measure reflectance of various wavelengths of an optical fiber reflector, an optical fiber is provided at an output port of a 50:50 coupler as shown in FIG. The reflector is connected to form a measuring device. A laser having a variable wavelength can be used as a signal light source and incident to one of the input ports of the coupler. A power meter is connected to the other input port of the coupler to detect signal light reflected from the optical fiber reflector. .

Referring to the operation of the reflectance measuring apparatus of the optical fiber reflector shown in FIG. 1, first, a power meter is connected to the coupler output port before connecting the coupler and the reflector to measure the wavelength dependency of the coupler. Then, the intensity of the input signal light is kept constant, the wavelength is changed, and the output of the signal light is measured. The wavelength dependence of the measured coupler is used to correct the measured reflectance after connecting the reflector. In addition, the reflected signal light also passes through the coupler, so connect the signal light source to the output port of the coupler and measure the power according to the wavelength at one of the input ports.

When measuring the signal reflected from the optical fiber reflector using a coupler, the configuration is simple, but the intensity of light is split into two ports after the reflected signal passes through the coupler. In this case, the intensity of light measured by the power meter is half the intensity of light reflected from the optical fiber reflector. In this case, since the reflected light is divided into exactly 50:50 regardless of the wavelength and passes through the coupler, the measured reflected wave intensity must be corrected again according to the wavelength. In other words, when the signal light passes through the coupler toward the optical fiber reflector and when the signal is reflected from the reflector and passes through the coupler, the loss characteristics of the coupler according to the wavelength should be measured and the reflectance of the reflector should be used as a correction factor.

Couplers do not block the light that is reflected from other devices, such as connectors, that are not optical fiber reflectors. Therefore, if you measure the reflectance of the optical fiber reflector in the above manner will include some error. If the intensity of the signal light is unstable, the reflectance of the optical fiber reflector is quite inaccurate. This is because the conventional technique of measuring reflectance of an optical fiber reflector does not measure input light and reflected output light at the same time. In other words, if the signal light source is unstable and the intensity changes during this time interval, the reflectance of the optical fiber reflector changes every time the measurement is made, resulting in poor reliability.

The present invention has been made to solve the above-mentioned problems, and can reduce the error caused by light reflected from a device such as a connector other than an optical fiber reflector, and prevent the phenomenon that the reflectance changes slightly every time the input light source is unstable. An object of the present invention is to provide a reflectance measuring apparatus and a measuring method of a reflecting optical fiber.

1 is a block diagram of a reflectance measuring apparatus of a conventional optical fiber reflector.

2 is a block diagram of an apparatus for measuring reflectance of an optical fiber reflector according to the present invention.

3 is a flowchart illustrating a method of measuring reflectance of an optical fiber reflector according to the present invention.

In order to achieve the above object, a reflectance measuring apparatus of an optical fiber reflector according to the present invention includes an input port for receiving an input light source and a first output port for dividing the input light source inputted into the input port into two lights and outputting each of them one by one. And a coupler having a second output port. A first input port for receiving the divided first output light of the coupler, an output port for receiving and outputting the light inputted to the first input port, and outputting the reflected light which is reflected back from the light output from the output port A circulator having a second input port; An optical fiber reflector reflecting light output to an output port of the circulator; And a power meter for measuring the light output through the second output port of the coupler and the reflected light output through the second input port of the circulator.

In accordance with another aspect of the present invention, there is provided a method for measuring reflectance of an optical fiber reflector using the optical fiber reflector measuring device, the method including: obtaining loss characteristics according to a wavelength of the circulator; Obtaining a loss characteristic according to the wavelength of the coupler and the circulator; Measuring the power of the second input port output light of the circulator and the second output port output light of the coupler with a power meter after connecting the output port of the circulator with the optical fiber reflector: Measuring the corrected reflected light intensity with varying wavelengths; And calculating the reflectance of the reflector by correcting the measured value of the corrected reflected light intensity according to the loss characteristic obtained above.

The calculating of the loss characteristic according to the wavelength of the circulator may include connecting a light source to an output port of the circulator, and measuring power at a second input port of the circulator while varying the wavelength. In addition, obtaining a loss characteristic according to the wavelength of the coupler and the circulator may include connecting a first output port of the coupler and a first input port of the circulator; And measuring a power at an output port of the circulator while varying a wavelength by connecting an input light source to the coupler.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 2 is a block diagram of an apparatus for measuring reflectance of an optical fiber reflector according to the present invention, and includes a coupler 200, a circulator 210, an optical fiber reflector 220, and a power meter 230.

The coupler 200 is a device for dividing or combining input light, an input port for receiving an input light source, a first output port for splitting the input light source inputted into the input port into two lights, and outputting one by one each; It has two output ports. The circulator 210 is an optical element used to block light reflected from a device other than an optical fiber reflector such as the connector 240 by differently a passage for receiving a signal and a passage for outputting the splitter of the coupler 200. A first input port for receiving the first output light, an output port for receiving and outputting the light inputted to the first input port, and a second input for outputting the reflected light which is reflected from the output port and is input again It has a port. The optical fiber reflector 220 reflects the light output to the output port of the circulator 210. The power meter 230 is a device for measuring light, and measures the light output through the second output port of the coupler 200 and the reflected light output through the second input port of the circulator 210.

In the exemplary embodiment of the present invention, the optical circulator 210 is used instead of the coupler to block the light reflected from the elements other than the optical fiber reflector such as the connector 240. The input signal light passes from the first input port of the circulator to the output port, and the output light reflected from the optical fiber reflector 220 passes from the output port of the circulator 210 to the second input port so that the reflected light is directed toward the input light source. It was not allowed to enter again. Since the circulator 210 has an isolation of 60 dB or more, the reflected light cannot enter the first input port at the output port of the circulator 210, and the light reflected from the output connector is reflected to the second input port of the circulator 210. You can't go back to the output port, so you can get stable data.

In case the input light source is unstable and the intensity of the light changes frequently, 99% of the light source is directed to the reflector 220 and 1% of the light source is measured by using two 99: 1 couplers 200 behind the light source. Power meter 230 can be measured at the same time with the reflected light. In this case, even if the input light source is somewhat unstable, since the input light and the reflected light are simultaneously measured, accurate reflectance can be measured. Also, in order to reduce the reflection of light from the input / output connector, a connector 240 having a 7 ° tilted end surface is used.

In addition, in order to measure the reflectance according to the wavelength change of the optical fiber reflector 220, a laser light source capable of changing the wavelength and a power meter 230 capable of measuring the intensity of two lights to simultaneously measure incident light and reflected light are used. In addition, the input / output connector 240 used a connector having a 7 ° tilted cross section to prevent reverse reflection.

3 is a flowchart illustrating a method of measuring a reflectance of an optical fiber reflector according to the present invention. Referring to FIG. 3, the operation of the present invention will be described. First, the loss characteristics according to the wavelength of the coupler 200 and the circulator 210 should be investigated. To this end, first, a loss characteristic according to the wavelength of the circulator 210 is measured. (Step 300) As a method for measuring the loss characteristic of the circulator 210, a light source is connected to an output port and the wavelength is changed. Measure the power at the second input port. Next, the first output port of the coupler 200 and the first input port of the circulator 210 are connected to calculate the coupler-circulator loss characteristic while varying the wavelength (step 310). Measuring the power at the output port of the circulator 210 while varying the wavelength by connecting the first output port of the circulator 210 and the first input port of the circulator 210 and connecting the input light source to the coupler 200. do. At this time, the intensity of the input light separated by 1% from the coupler 200 is simultaneously measured by the power meter 230. The loss characteristics according to the wavelength of the coupler 200 and the circulator 210 measured as described above are used as a correction value for measuring pure reflectance of the reflector only when calculating the reflectance of the reflector by measuring the reflected light reflected from the optical fiber reflector.

After connecting the output port of the circulator 210 and the optical fiber reflector, the power at the second input port of the circulator 210 is measured with a power meter at the same time as the 1% port of the coupler 200 (step 320). The intensity of the reflected light corrected for the power change of the input light source is measured at different wavelengths (step 330). The measured result considers the loss characteristics according to the wavelengths of the coupler 200 and the circulator 210 measured above. If corrected, the accurate reflectance of the optical fiber reflector can be measured (step 340).

On the other hand, when the tunable laser light source and power meter are connected to a personal computer through a GPIB interface, the reflectance of the optical fiber reflector can be measured accurately and simply.

According to the present invention, when measuring the reflectance of the optical fiber reflector using only the coupler, which has been a problem in the prior art, not only part of the light reflected from the reflector enters the input light source, but also makes the output of the light source unstable and the intensity of the light emitted from the light source may change. In this case, there is no way to correct this problem.

In addition, since the circulator is essentially used to configure the recycle erbium-doped fiber amplifier (REDFA), if the circulator is used to measure the reflectance of the optical fiber reflector as in the present invention, the erbium doped optical fiber between the circulator and the optical fiber reflector after the reflectance measurement ( When the EDF) is inserted, it becomes a REDFA structure immediately, and thus it is expected to increase productivity.

Claims (3)

Coupler for splitting the input light source into two light through the first output port and the second output port, the first light receiving the split first output light of the coupler and outputs to the output port and the reflected light input to the output port Is a circulator for outputting to the second input port, a reflector for reflecting the output light of the circulator and the output light to the second output port of the coupler and the power of the reflected light output to the second input port of the circulator for measuring In the method of measuring the reflectance of an optical fiber reflector using the optical fiber reflector measuring apparatus comprised including a power meter, Obtaining a loss characteristic according to the wavelength of the circulator; Obtaining a loss characteristic according to the wavelength of the coupler and the circulator; After connecting the output port of the circulator and the optical fiber reflector, measuring the power of the second input port output light of the circulator and the output light of the second output port of the coupler with a power meter: Measuring the corrected reflected light intensity with respect to the power change of the input light source by changing the wavelength; And And calculating a reflectance of the reflector by correcting the measured value of the corrected reflected light intensity according to the obtained loss characteristic. The method of claim 1, wherein the obtaining of the loss characteristic according to the wavelength of the circulator Connecting a light source to an output port of the circulator: and And measuring power at a second input port of the circulator while varying the wavelength. The method of claim 1, wherein the obtaining of the loss characteristic according to the wavelength of the coupler and the circulator is performed. Connecting a first output port of the coupler and a first input port of the circulator; And And measuring a power at an output port of the circulator while varying a wavelength by connecting an input light source to the coupler.