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For actively modulated In-line Sagnac interferential all optic fiber current transformers (AOFCTs), the accuracies are directly affected by the amplitude of the modulation signal. In order to deeply undertand the function of the modulator, a theoretical model of modulation effect to AOFCTs is built up in this paper. The effect of the amplitude of the modulation signal to the output intensity of AOFCTs is theoretically formulated and numerical calculated. The results show that the modulation voltage variation could affect the output accuracies significantly. This might be some references on the investigation for practical applications of AOFCTs.

At present, Electronic Current Transformers (ECTs) are widely used in power systems. Comparing with other kinds of ECTs, all optical fiber current transformers (AO FCTs) have been considered mainly for applications in high, ultra high, even high voltages substations. Most of reported articles about AOFCTs were based on the theory and technology of fiber optic gyroscope [1,2]. Ordinary Sagnac type interferometers have received considerable attention for optical fiber current transforming, because of their advantages [3-6] such as: optical fiber loop is located in high voltage area (without any electronic component), so it is easy to solve the problems like high-voltage partial discharge, insulation problems and electromagnetic shielding effectiveness. Moreover, in the high voltage area the elements of AOFCT are small and light [7-8]. In-line configuration [

According to the Faraday effect, the rotation of the plane of polarization is proportional to the intensity of the applied magnetic field in the direction of light propagation. The Faraday rotation angle is proportional to the component of the magnetic field along the propagating direction of the light beam. For a closed optical loop, applying the Ampere’s law, the formula of the Faraday effect can be written as

where V is the Verdet constant of the fiber, N is number of sensing coils and i is the current intensity to induce the effect. As Faraday rotation angle is very small, it may bring significant difficulties to detect the angle directly in AOFCTs without necessary phase shift. Therefore, it is necessary to add a phase modulator for easier detecting and achieving better accuracies. Accuracies of a few tenths of a percent are required for metering applications of ECT, and much better accuracies are required for certain incipient fault detection applications such as detecting the presence of leakage currents. Therefore, a careful analysis respect to modulation errors should be given to show how they affect the current transformers’ performance.

Nowadays, the reported achievements about modulation methods could divide into two groups: active modulation and passive modulation. The analysis about the effect of modulation errors of passively modulated AO FCTs was detailed in reference [

For In-line AOFCTs, the reference frame (x, y, z) has its x and y axes at 45˚ with respect to the input linear polarization, the HiBi fiber has its birefringence axes parallel to the x and y axes and the orientation of the z axis is given by the propagation vector. The layout of an active modulation AOFCT is shown in

The optical vector emerging from the source can be described as E. After being launched into the fiber polarizer, the output light E_{in} of the polarizer, which will be lunched into the HiBi fiber delay line, can be represented by the Jones vector as

Suppose that the HiBi fiber is an ideal one, which means that no cross coupling arises from one birefringence axis to the other, the Jones matrices for forward and backward propagation of a light beam in the HiBi are the same, which could express by the Jones matrix as

Here the right direction arrow represents forward propagation, and the left one represents backward propagation and is the phase difference between the two modes propagating in the two principal axes of the HiBi fiber, respectively. The principal axes of a quarter wave retarder are connected at a 45˚ angle with respect to that of the HiBi fiber. The Jones matrices of the retarder can be given as

For the leading fiber, the use of highly twisted fiber can increase the circular birefringence of the fiber to quench its intrinsic linear birefringence. The circular birefringence of the leading fiber is reciprocal, hence the Jones matrices of the leading fiber for forward and backward propagation have the same form, which can be expressed as

where is the rotation angle induced by the highly

circular birefringence fiber.

In the sensor head part, the fiber used to compose the sensing coil is the same as the leading one. Thus they have identical Jones matrix representations. Because the Faraday effect is nonreciprocal, its induced term becomes negative for backward propagation. As the Faraday effect occurs, the induced extrinsic circular birefringence should superimpose onto the intrinsic one. So the Jones matrix representations for the sensor head could be represented as

where is the rotation angle in the highly twisting circular birefringence fiber.

The mirror is represented by the Jones reflection matrix

The output E_{out} at the connecting point between the fiber polarizer and the leading part is described as

By means of Jones matrix manipulation, the result can be shown as

To get the interference between the two orthogonal polarizations at the output, a linear polarizer with its transmission axis aligned at 45˚ with respect to the reference axis has to be introduced.

When the reflected light E_{out} is launched into the fiber polarizer, interference occurs. The interference E_{t} in the output electrical field form is represented as

Without further measures, the detected intensity resulting from the interference of the returning waves is given by

where and (“+” means Hermitian operators).

Equation (12) indicates that when the bus current intensity is very small, the detecting accuracy would be very small, because of the cosine function. Therefore, it is necessary to add a phase shift to move the working point to the most sensitive position.

PZT is one of the most widely used phase modulator. Under the control of the modulation signal u(t), the length L and refractive index n of the optical fiber wound around the PZT will correspondingly change to realize the phase modulate function. The phase variation of the fiber [

where is light wavelength in vacuum, is gauge factor of fiber, and is the length variation of fiber.

where, r_{1} and r_{2} are the internal and external radius of the PZT, is the Poisson ratio of fiber, k_{dp} is load coefficient, d_{31} is piezoelectric strain constant and A_{E} is a constant associate with PZT material. To analyze the relationship between modulation signal and the detected output optical intensity.

The phase modulation signal could be written as. Where U_{0} is the amplitude of the modulation signal and is the modulation frequency. Here it is supposed that the is a constant, because we are only interested in the effect of the U_{0}_{, }although the is changeable with the environment factors. Accordingly, Equation (12) become

where

Ideally, should equal to

−p/2 (means), but it can be seen form the equation that the amplitude of the modulation signal U_{0}, the modulation frequency and the length of fiber L are the key factors to the output optical intensity. For a given In-line typed optical current transformer, ignoring any other influenced factor, and L are fixed, so the main factor become U_{0}.

To assess the effect of the amplitude of the modulation signal on the output, the transformer is assumed that all optical devices used are ideal except the modulator. And only the effect of U_{0} is taken into consideration. The normalized is used. Then one has

and

Assuming, matching the modulation frequency and the time delay

(means), then L = 861 m could be obtained.

Take as an example, the output error of the system is defined as

Equation (16) has its variable U_{0} and t. The simulation results are plotted in _{0} ranging from 4.9 to 5.1 V.

The pattern in

As depicted in Figures 3(a) and (b), if the magnitude of voltage shift is larger than 0.01 V from 5 V, the resulting output error would be greater than 0.2% of the ideal value and become unacceptable due to standards determined by the International Standard IEC 60044- 8:2002 [

carefully designed.

An analysis of modulation error associated with modulating voltage to the modulator of the AOFCTs has been calculated. The effects of the modulation voltagevariation used in the system on the performance of modulation signal to the AOFCTs have been theoretically analyzed, corresponding numerical calculation results have also been given. The results reported here indicate that even though the active modulation method has many advantages, the stability of the amplitude of modulation signal must still be taken into consideration during the design procedures for those practical applications.