KR100950150B1 - Optical signal to noise ratio measurement apparatus and method - Google Patents

Abstract

An apparatus for measuring the signal-to-noise ratio of an optical signal of the present invention is disclosed.

The optical signal-to-noise ratio measuring device of the present invention divides an optical signal into two vertically polarized states and winds a polarization-maintaining optical fiber that provides different optical paths to a cylindrical piezoelectric element that expands and contracts at regular intervals according to an AC signal. It causes phase difference in one optical path, and combines and interferes with optical signals passing through two vertical optical paths, and converts them into electrical signals to measure the signal and noise ratio of optical signals by measuring the magnitude of the AC and DC components of the electrical signal. Measure

Description

Optical signal to noise ratio measurement apparatus and method

1 is a diagram showing a spectrum of an optical signal passing through an optical amplifier.

FIG. 2 is a diagram illustrating an optical signal applied to a polarization maintaining optical fiber traveling along two vertical axes. FIG.

3 is a block diagram showing the configuration of an optical signal to noise ratio measuring apparatus according to the present invention.

4 is a view illustrating a method of aligning an optical signal input by a polarization controller to a polarization maintaining optical fiber.

5 is a cross-sectional view of a piezoelectric element 33 wound around a polarization maintaining optical fiber 20 according to the present invention.

6 shows waveforms of optical signals detected by a photodetector.

The present invention relates to an apparatus and a method for measuring an optical signal-to-noise ratio indicating the performance of an optical signal in an optical communication network using an optical amplifier, and more particularly, by using a piezoelectric element (Pizoelectric Transducer) wound around the polarization holding optical fiber The present invention relates to an apparatus and method for measuring optical signal-to-noise ratios simply and accurately while minimizing the effects of external environmental changes.

In general, in an optical communication network using an optical amplifier, when the optical signal passes through the optical amplifier, the optical signal is amplified and natural emission light (ASE) noise is added to the optical signal. Since the ASE noise accumulates as it passes through several optical amplifiers, it acts as a major factor that degrades the performance of the optical signal.

Therefore, in order to establish a stable optical communication network, it is necessary to accurately monitor the performance of the optical signal by accurately measuring the optical signal to noise ratio indicating the performance of the optical signal.

1 is a diagram illustrating a spectrum of an optical signal passing through an optical amplifier.

When the optical signal passes through the optical amplifier, the ASE noise 11 is added in addition to the optical signal 10. Equation for the optical signal to noise ratio of the optical signal is shown in Equation 1 below.

[Equation 1]

Therefore, in order to accurately measure the optical signal-to-noise ratio, the optical signal strength and the ASE noise included in the optical signal must be measured. The proposed method for measuring the optical signal-to-noise ratio includes an optical spectrum analyzer having a diffraction grating and a photodetector array.                         

However, such a configuration has a disadvantage in that it is difficult to secure a high cost and an area to be applied to an actual optical communication network due to the use of bulky and expensive optical instruments such as a diffraction grating and a photodetector.

In order to overcome this disadvantage, optical signal-to-noise ratio monitoring using an asymmetric Mach-Zehnder interferometer (see domestic patent application: 2000-0049868) has been proposed. This technique uses an asymmetric Mach-Zehnder interferometer with two different arms to split the coherent and incoherent light sources for simple and low cost optical signal to noise ratio measurements. Way.

However, this technique uses two different arms to measure an asymmetric Mach-Zehnder interferometer so that the two arms do not react equally to changes in the external environment, so that the optical signals passing through the two arms undergo different phase differences to measure accurate optical signal-to-noise ratios. Is very well known in the art. In particular, when the intensity of the input optical signal is small and the optical signal-to-noise ratio is small, the value of the measurement error caused by the external environmental change may be very large.

Accordingly, an object of the present invention for solving the above problems is to measure the optical signal-to-noise ratio simply and accurately while minimizing the influence of external environmental changes.

Optical signal to noise ratio measuring apparatus of the present invention for achieving the above object is a polarization controller for inputting an optical signal in a specific direction of the polarization maintaining optical fiber; An optical signal interferer for dividing the optical signal input by the polarization controller into two vertical polarization states to provide different optical paths, and causing a phase change in one of the two vertical optical paths; A polarization combiner for combining and interfering optical signals passing through two perpendicular optical paths of the optical signal interferer; A photodetector for converting the interfering optical signal into an electrical signal; And a signal processor for measuring an optical signal to noise ratio of the optical signal by measuring a signal component and a noise component from the electrical signal output from the photodetector.

The optical signal-to-noise ratio measuring method of the present invention comprises a first step of dividing an optical signal into two vertically polarized states; Generating a phase difference between the two optical paths by changing a phase of one of the two vertical optical paths; Combining and interfering optical signals passing through the two optical paths in which the phase difference is generated; And a fourth step of converting the interfering optical signal into an electrical signal and measuring the optical signal to noise ratio of the optical signal by using the waveform of the converted signal.

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

FIG. 2 is a diagram illustrating a state in which an optical signal applied to a polarization maintaining optical fiber travels along two vertical axes, and illustrates a principle of using an optical fiber as an interferometer.

The optical signal 21 input at 45 ° to the two vertical axes 22 and 23 of the polarization maintaining optical fiber 20 is divided into two vertical polarization states and proceeds. In this case, when the optical fiber 20 is an ideal circular shape, the speed of the signal traveling along the two traveling shafts 22 and 23 is the same. Different refractive indices result in different propagation speeds.

That is, since the optical signal 25 traveling to the short axis 22 has a relatively small refractive index compared to the optical signal 24 traveling to the long axis 23, the optical signal 25 is output faster than the optical signal traveling to the long axis. As a result, a phase difference occurs between the optical signals to be output, thereby causing interference with each other when polarizing the optical signals.

Therefore, an interferometer having two arms can be configured using one polarization maintaining optical fiber 20.

3 is a block diagram showing the configuration of an optical signal to noise ratio measuring apparatus according to the present invention.

The polarization controller 31 inputs the input optical signal to the polarization maintaining optical fiber 20 in a specific direction. In the present invention, an optical signal is applied in a 45 ° direction between two perpendicular traveling axes 22 and 23 of the polarization maintaining optical fiber 20. At this time, the ASE noise is amplified and added to the signal component in the optical signal amplified and input to the polarization controller 31.

4 is a diagram illustrating a method of aligning an optical signal input by the polarization controller 31 to a polarization maintaining optical fiber. The polarization controller 31 allows the direction 41 of the polarization controller to be positioned at 45 ° between the two axes so that the input optical signal is distributed at the same light intensity on the two vertical axes 22 and 23 of the polarization maintaining optical fiber 20.

The piezoelectric element 33 is formed in a cylindrical shape so as to wind the polarization maintaining optical fiber 20, and the polarization maintaining optical fiber 20 is wound by expanding and contracting in diameter according to an AC signal of a predetermined period output from the AC signal generator 32. This results in a phase shift in either of the two perpendicular paths.

5 is a cross-sectional view of the piezoelectric element 33 in which the polarization maintaining optical fiber 20 is wound in accordance with the present invention. The direction of one of the two propagation axes 23 of the polarization maintaining optical fiber 20 is wound so as to be parallel to the direction in which the piezoelectric element 33 expands or contracts in accordance with the AC signal. That is, pressure is applied to the traveling axis 23 by expansion or contraction of the piezoelectric element 33, causing a phase difference between two perpendicular axes of the polarization maintaining optical fiber.

As such, the polarization maintaining optical fiber 20, the AC signal generator 32, and the piezoelectric element 33 are used as optical signal interferers for interfering optical signals traveling in a vertical polarization state.

Furthermore, since the polarization maintaining optical fiber is wound several times on the cylindrical piezoelectric element 33, even when a low alternating current voltage is applied, it can cause a large phase difference, which indicates that the present invention can lower the power consumption.

The polarization combiner 34 couples the optical signals passing through two paths of the polarization maintaining optical fiber 20 wound on the piezoelectric element 33.

The photodetector 35 detects the polarized optical signal and converts it into an electrical signal having the same information.

The signal processor 36 measures a signal component and a noise component in the electrical signal output from the photodetector 35 to measure the optical signal to noise ratio of the optical signal.

The operation of the optical signal to noise ratio measuring device having the above-described configuration will be briefly described as follows.                     

The polarization controller 31 maintains the polarization wound around the piezoelectric element 33 by causing the optical signal amplified by the optical amplifier (not shown) to be 45 ° between two perpendicular traveling axes 22 and 23 of the polarization maintaining optical fiber 20. Input to the optical fiber 20. This is because under these conditions, the strength of the interfering signal is measured the largest.

The optical signal applied to the polarization maintaining optical fiber 20 is a mixture of signal light and ASE noise. The signal light has a relatively long coherence length and a specific polarization state, but the ASE noise has a shorter coherence length than the signal light. It exists in the state of no polarization.

When the input optical signal having such optical characteristics is input to the polarization maintaining optical fiber 20 using the polarization controller 31, the optical signal is divided into two vertical components and the branched optical signal is the same polarization maintaining optical fiber 20. It will go through different paths within.

At this time, as shown in FIG. 5, the low frequency AC signal generated by the AC signal generator 32 is applied to the piezoelectric element 33 on which the polarization maintaining optical fiber 20 is wound.

The piezoelectric element 33 receiving the AC signal repeats expansion and contraction according to the AC signal, and thus the piezoelectric element 33 travels along the traveling axis 23 in a direction parallel to the direction in which the piezoelectric element 33 expands and contracts. The optical signal experiences a different phase difference compared to the optical signal passing through another vertical path 22.

As such, when the output signals of the polarization maintaining optical fibers 20 which have experienced different phase differences are combined in the polarization combiner 34, the optical signals which have experienced different phase differences interfere with each other. In this case, the signal light maintains a specific polarization state. Although interference phenomenon appears, ASE noise is polarized light with all polarization states, so the interference by each polarization cancels each other and the interference effect disappears.

That is, when the polarized light signal is converted into an electrical signal through the photodetector 35 and then detected by the signal processor 36, the detected waveform has a shape as shown in FIG. 6.

That is, in the case of the signal will have an AC component (Vs) by the interference, in the case of the ASE noise is only when eliminating the interference effects, mainly the DC component (V _ASE).

The signal processor 360 measures the magnitude of the AC component of the waveform 61 to measure the optical signal-to-noise ratio (Vs / V _ASE ) of the optical signal.

As described above, a single polarization maintaining optical fiber is wound around the piezoelectric element to form an interferometer that causes a phase shift between two perpendicular traveling axes of the optical fiber, thereby stably using optical signal difference between the signal component of the optical signal and ASE noise. The signal-to-noise ratio can be measured, and its structure is simple, so that an optical signal-to-noise ratio measuring device can be economically implemented.

Claims (9)

A polarization controller for inputting an optical signal in a specific direction of the polarization maintaining optical fiber; An optical signal interferer for dividing the optical signal input by the polarization controller into two vertical polarization states to provide different optical paths, and causing a phase change in one path of the two vertical optical paths; A polarization combiner for combining and interfering optical signals passing through two perpendicular optical paths of the optical signal interferer; A photodetector for converting the interfering optical signal into an electrical signal; And A signal processor for measuring an optical signal to noise ratio of the optical signal by measuring a signal component and a noise component from the electrical signal output from the photodetector, The optical signal interferer A polarization maintaining optical fiber dividing the input optical signal into two vertical polarization states to provide different optical paths; An AC signal generator for outputting an AC signal at a predetermined cycle; And a cylindrical piezoelectric element wound around the polarization maintaining optical fiber and causing expansion and contraction in accordance with the AC signal to cause a phase change in one of two vertical optical paths of the wound polarization maintaining optical fiber. The signal processor And measuring the magnitudes of the AC and DC components of the electrical signal to measure the optical signal-to-noise ratio of the optical signal. Optical signal to noise ratio measuring device, characterized in that. According to claim 1, wherein the polarization regulator And receiving the optical signal in a 45 ° direction between two vertical optical paths of the polarization maintaining optical fiber. delete The method of claim 1, wherein the polarization maintaining optical fiber And an optical signal-to-noise ratio measuring device wound around the cylindrical piezoelectric element such that the direction of one of the propagation axes of the two vertical optical paths is parallel to the direction in which the cylindrical piezoelectric element expands and contracts. delete Dividing the optical signal into two vertical polarization states and proceeding to two vertical optical paths in the polarization maintaining optical fiber; Generating a phase difference between the two optical paths by changing a phase of one of the two optical paths; Combining and interfering optical signals passing through the two optical paths in which the phase difference is generated; And And converting the interfering optical signal into an electrical signal, measuring an AC component and a DC component of a waveform of the converted signal, and measuring the optical signal to noise ratio of the optical signal using the ratio. The method of claim 6, wherein the second step A method of measuring an optical signal-to-noise ratio, characterized in that to generate a phase difference between two optical paths by applying a constant period of pressure in one of two perpendicular axes of a polarization maintaining optical fiber. 8. The method of claim 7, wherein the second step is The polarization-maintaining optical fiber is wound around the cylindrical piezoelectric element such that the one direction is parallel to the direction in which the cylindrical piezoelectric element is expanded and contracted, and the optical fiber is expanded and contracted by applying an AC signal to the cylindrical piezoelectric element. Signal to noise ratio measurement method. delete

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