KR20040000694A - Apparatus for compensating polarization mode dispersion - Google Patents

Abstract

PURPOSE: A polarization mode dispersion compensating apparatus is provided to dynamically compensate polarization mode dispersion by using a polarization-maintenance fiber wound at a polarization splitter and a piezoelectric transducer. CONSTITUTION: A polarization mode dispersion compensating apparatus is provided with an optical switch(120) for switching an optical signal, a polarization controller(130) for maintaining the modulated optical signal transmitted from the optical switch a constant polarization state, a polarization-mode dispersion compensator(140) for compensating the polarization mode dispersion of the optical signal inputted from the polarization controller, and an optical power splitter(150) for preventing the polarization variation of the optical signal transmitted from the polarization-mode dispersion compensator. The polarization mode dispersion compensating apparatus further includes a differential group delay measuring unit(160) and a compensation controller(170).

Description

Apparatus for compensating polarization mode dispersion

The present invention relates to a polarization mode dispersion compensation device, and more particularly, using a piezoelectric transducer wound around a polarization splitter and a polarization maintaining optical fiber, to differentiate differential group delay between two perpendicular polarizations. And a polarization mode dispersion compensation device that optically compensates polarization mode dispersion caused by a modulated optical signal due to an optical path or an optical element.

Polarization mode dispersion is a phenomenon caused by the birefringence of the optical fiber.

Birefringence refers to the difference in refractive index between an optical fiber core having an elliptic shape rather than a perfect circle or between the fundamental modes of an optical fiber due to external stress.

Such birefringence causes a differential group speed difference between two perpendicular polarizations of the optical signal incident on the optical fiber, causing pulse spreading.

This pulse spreading must compensate for this phenomenon because it degrades the transmission signal.

Transmission degradation due to polarization mode dispersion is the biggest factor that limits the transmission performance of the actual system as the transmission speed increases.

Therefore, the International Telecommunications Union-Telecommunication Standardization Sector (ITU-T) specifies that in the case of 10G systems, the pulse spread due to dispersion of polarization mode is less than 10% of the pulse width of the signal, assuming a 1 dB penalty. have.

When applied to 40G systems, the maximum differential speed difference that the system can tolerate is 2.5 ps, which is very small.

The maximum distance that can be transmitted when applying this criterion is only a few tens of kilometers, so to increase the transmission distance, the polarization mode dispersion must be compensated.

In order to compensate for the polarization mode dispersion, the conventionally proposed method has been proposed to electrically compensate in the optical receiver and to use optical fiber and chirp brag grating.

However, the method of using the optical receiver has the disadvantage that the structure of the receiver is complicated and the system price is increased.

The method using optical fiber and chirp brazing is difficult to make with current technology, and the difference of differential group speed difference due to temperature change of chirp bratting and the value of polarization mode dispersion that can be compensated for are small. There are disadvantages.

In order to solve the above problems, an object of the present invention is to dynamically compensate for polarization mode dispersion using a polarization maintaining optical fiber wound on a polarizer and a piezoelectric element for a high speed modulated optical signal.

1 is a block diagram of a polarization mode dispersion compensation apparatus according to the present invention.

FIG. 2 is a diagram illustrating an internal configuration of the polarization mode dispersion compensator of FIG. 1.

3 is a view illustrating an internal polarization state measuring unit of the differential group speed difference measuring unit of FIG. 1.

4 is a diagram illustrating an internal configuration of the compensation controller of FIG. 1.

To this end, the polarization mode dispersion compensation apparatus according to the present invention, the optical switch for switching the optical signal; A polarization controller for maintaining the modulated optical signal transmitted from the optical switch in a constant polarization state; A polarization mode dispersion compensator for compensating polarization mode dispersion of the optical signal input from the polarization controller; An optical power divider for preventing the polarization of the optical signal transmitted from the polarization mode dispersion compensator to be changed; A differential group speed difference measuring unit measuring a differential group speed difference of the optical signal transmitted from the optical power splitter; And a compensation controller configured to process the differential group speed difference value transmitted from the differential group speed difference measurer to control the polarization mode dispersion compensator.

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

1 is a block diagram of a polarization mode dispersion compensation device according to the present invention, the optical switch 120 for switching the optical signal, the polarization mode dispersion compensation unit for compensating the polarization mode dispersion of the optical signal input from the optical switch 120 140, a polarization controller 130 for inputting the modulated optical signal to the polarization mode dispersion compensator 140 in a constant polarization state, an optical power divider 150 for preventing polarization from changing, and a differential group speed of the transmitted optical signal A differential group speed difference measuring unit 160 for detecting a difference and a compensation control unit 170 for controlling the polarization mode dispersion compensation unit 140 are provided.

Referring to the operation, first, the optical signal modulated at 10 Gbps or more generated from the light source 110 passes through the optical element causing the polarization mode dispersion such as the optical fiber, and then through the optical switch 120 through the polarization mode dispersion compensation unit 140 Is entered.

In this case, in order to input the polarized mode distributed optical signal in a constant polarization state, the polarization mode dispersion compensator 140 is input through the polarization controller 130.

Then, the polarization mode dispersion compensator 140 transmits the optical signal to the differential group speed difference measurement unit 160 while preventing the polarization from changing using the optical power splitter 150 of polarization independent 10:90.

Then, the differential group speed difference measuring unit 160 calculates the differential group speed difference due to the polarization mode dispersion of the transmitted modulated optical signal and transmits the value to the compensation controller 170.

At this time, the differential group speed difference measuring unit 160 and the compensation control unit 170 transmits data through the RS232c interface.

Then, the compensation controller 170 compensates for the polarization mode dispersion by generating a control signal to the polarization mode dispersion compensator 140 according to the value of the differential group speed difference transmitted from the differential group speed difference measurement unit 160.

Then, the differential group speed difference of the optical signal passing through the polarization mode dispersion compensator 140 is measured again by the differential group speed difference measurement unit 160, and the compensation control unit 170 according to the value of the changed differential group speed difference, the polarization mode dispersion By controlling the compensator 140, the polarization mode dispersion of the optical signal is compensated through this repeated process.

2 is an internal configuration diagram of the polarization mode dispersion compensator 140 of FIG. 1, followed by two polarization separators 210 and 220 and two polarization separators 210 and 220 for separating or combining the polarization of the optical signal. Polarization maintaining optical fibers 230 and 240 forming two paths and piezoelectric elements 250 and 260 wound around the respective optical fibers 230 and 240 are provided.

One of two paths consisting of polarization maintaining optical fibers 230 and 240 is a relatively fast path, and one is a slow path.

First, the polarization separator 210 decomposes an input optical signal into two vertical polarizations 270 and 280 and inputs the two signals of the polarization separator 210.

For example, one component 270 of the vertically polarized light from the polarization separator 210 is made to enter the fast path 230 of the polarization maintaining fiber located in the upper path, and the other vertically polarized light from the polarization separator 210 is made. 280 allows incident on the slow path 240 of the polarization maintaining optical fiber.

The polarization maintaining optical fibers 230 and 240 are respectively wound around the cylindrical piezoelectric elements 250 and 260, and the number of windings can be arbitrarily adjusted according to the value of the differential group speed difference to be compensated for.

The two vertical polarizations 270 and 280 compensated by the differential group speed difference to be compensated by the piezoelectric elements 250 and 260 positioned in the two paths 230 and 240 are separated by the polarization splitter 220 on the opposite side. The output is merged again.

Here, the principle of giving the differential group speed difference between the vertical polarization passing through the two paths is as follows.

Since the piezoelectric element contracts or expands when a voltage is applied, the length of the polarization maintaining optical fiber wound on the piezoelectric element is increased or decreased, thereby giving a relative differential group speed difference value between the two paths.

For example, in the case to compensate for differential group velocity difference value of 10ps fixing the piezoelectric elements in one path, and applying a voltage to the piezoelectric element in the other path to 3 × 10 ⁸ of (m / sec) × 10ps = 3mm Only the change in length can compensate for the 10ps polarization mode dispersion.

When the polarization maintaining optical fiber is wound n times on a cylindrical piezoelectric element, the length (radius) that the actual piezoelectric element should shrink or expand is 3 mm / (2 × pi × n).

Therefore, even when a signal having a low voltage is applied, the large polarization mode dispersion can be compensated, and thus, the power consumption of the present invention is very low.

In addition, since the differential group speed difference value to be compensated is a relative time delay value between two paths, when the differential group speed difference value to be compensated for is small, the present invention may be economically constructed by removing the piezoelectric elements located on one path.

The optical signal compensated by the polarization mode dispersion compensator 140 is compensated by measuring the differential group speed difference again in the differential group speed difference measuring unit 160, and the measurement of the differential group speed difference is generally used. Although a device capable of measuring differential group speed difference values may be used inside the mode meter, in general, since they take a long time to measure the differential group speed difference, the present invention provides a state of polarization of an optical signal as shown in FIG. 3. A polarization state meter 310 is shown.

Thus, a method of calculating the differential group speed difference value in the polarization state measuring device 310 will be described below.

The optical signal that has undergone polarization mode dispersion draws an arc 320 as shown on the Poangcurry sphere of the polarization state meter 310.

The differential group velocity difference value of the modulated optical signal is given by dividing the length of the arc on the Poangcurry sphere by the spectral width of the modulated optical signal.

The value of the arc is calculated as a value of θ, and the spectral width of the modulated optical signal is a value generally given the modulation rate.

Such calculation may be implemented in software in a commercially available polarization state meter 310.

The compensation for polarization mode variance is to change the value of the differential group velocities to bring these arcs to a point on the sphere.

4 is a detailed configuration diagram of the compensation controller 170 for controlling the polarization mode dispersion compensator 140 to receive the differential group speed difference value calculated by the differential group speed difference measurement unit 160 so that the differential group speed difference value becomes 0. to be.

The compensation controller 170 processes the control signal generators 410 and 420 by processing the differential group speed difference values and the control signal generators 410 and 420 which transmit pulse control signals to the piezoelectric elements of the polarization mode dispersion compensator 140. It has a central processor 430 for controlling.

When the polarization mode dispersion compensation device according to the present invention operates for the first time, the central processing unit 430 of the compensation controller 170 controls the optical switch 120 to compensate for the optical signal input from the polarization mode dispersion compensation. It is connected directly to the differential group speed difference measuring unit 160 without passing through the unit 140 to measure the initial differential group speed difference value.

Then, while storing the measured differential group speed difference value in the buffer and simultaneously operating the optical switch 120 so that an input optical signal is input to the polarization mode dispersion compensator 140, one of the polarization mode dispersion compensator 140 Compensation occurs in the polarization mode dispersion compensator 140 by applying the control signal set by the differential group speed difference value measured initially to the piezoelectric element positioned in the path.

Then, when the differential group speed difference measurement unit 160 transmits the differential group speed difference value again by the signal from the polarization mode dispersion compensator 140, the value is compared with the differential group speed difference value stored initially. If the value is larger than the differential group speed difference value stored earlier, the voltage of the control signal applied to the piezoelectric element that is initially set to be applied to the high voltage is decreased, and the voltage of the control signal applied to the piezoelectric element located on the other path is slightly increased. .

If this process is repeated until the differential group speed difference value stored in the buffer and the value transmitted from the differential group speed difference measuring unit 160 are the same, the polarization mode dispersion of the modulated optical signal in the optical path and the optical device is compensated.

As described above, as the transmission speed is increased to 10 Gbps or more, the present invention compensates the polarization mode dispersion by using the differential group speed difference in the optical domain by using a piezoelectric element wound with a polarization splitter and a polarization sustaining optical fiber, Direct polarization mode dispersion is compensated for, so there is no need for electrical conversion and can be used regardless of the transmission rate.

In addition, since the piezoelectric elements are provided in two paths of the polarization separator, a relatively large polarization mode dispersion can be compensated for.

In addition, the transparency of the signal, low cost and installation operability has the effect of enabling a high-speed large-capacity communication service.

Claims (3)

An optical switch for switching an optical signal; A polarization controller for maintaining a modulated polarization state of the modulated optical signal transmitted from the optical switch; A polarization mode dispersion compensator configured to compensate polarization mode dispersion of the optical signal input from the polarization controller; An optical power divider for preventing the polarization of the optical signal transmitted from the polarization mode dispersion compensator from changing; A differential group speed difference measuring unit measuring a differential group speed difference of the optical signal transmitted from the optical power splitter; And And a compensation control unit (170) for controlling the polarization mode dispersion compensator by processing the differential group speed difference value transmitted from the differential group speed difference measuring unit. The method of claim 1, The polarization mode dispersion compensation unit, A plurality of polarization separators that separate or combine the polarizations of the optical signals; A polarization maintaining optical fiber constituting a plurality of paths following the plurality of polarization separators; And And a plurality of piezoelectric elements wound around the polarization maintaining optical fiber, respectively. The method according to claim 1 or 2, The compensation control unit, A plurality of control signal generators for transmitting a control signal in a pulse form to the piezoelectric element; And a central processing processor for controlling the optical signal and controlling the control signal generator by processing the differential group speed difference value. The central processing processor controls the optical switch at an initial stage of operation so that the differential group speed difference measurer calculates the differential group speed difference value of the optical signal, stores the initial value of the differential group speed difference, and stores the initial value of the differential group speed difference. Using the control signal generator to transmit a control signal to the polarization mode dispersion compensator, Subsequently, when the differential group speed difference measurement unit measures and transmits a differential group speed difference value of the optical signal compensated by the polarization mode dispersion compensator, the differential group speed difference value is compared with the initial value of the differential group speed difference previously stored. Transmitting a control signal to the polarization mode dispersion compensator while updating the differential group speed difference to the differential group speed difference; Repeating the above process, the polarization mode dispersion compensation device, characterized in that for compensating the polarization mode dispersion of the optical signal until the differential group speed difference value is equal to the previously stored differential group speed difference value.