^{1}

^{*}

^{2}

^{3}

^{2}

The growth in the capacity of electric power system creates a demand for the protection of relaying systems. Optical current transducers—OCT that are mainly made up of single mode optical fibers which are subjected to Faraday rotation are used as a replacement for electromagnetic transducers due to their immunity to electromagnetic interference. However, the principal parameter in this system, the sensitivity to magnetic fields or current, depends on the Verdet constant, which is low in the case of optical fibers. However, the optical path length can be increased to compensate for it by winding the fiber around a current carrying element a large number of turns. In this work, we study a current sensor, which is made up of a conductor coil with a fiber inside, thus increasing sensitivity. We study the effect of the inhomogeneity of the magnetic field induced by the current on the sensitivity of the optical fiber sensor.

The protection of relaying systems is a prominent task for optical current sensors. These sensors can recognize sudden failures, such as surges, and identify the failure parts in the power systems. These relaying systems require current sensors, which are mostly electromagnetic devices that suffer from magnetic saturation effects and residual field effects. Recently several studies use optical current sensors as replacement for these established systems. Optical current sensors with mainly optical fibers do not suffer from electromagnetic interference, has light-weight and small size, and possess a low susceptibility to environmental influences [

The concept of the optical sensors is the magnetooptical principle. Thus, it is named magneto-optical sensor (MO). The magneto-optical sensor is based on the Faraday rotation effect [

In optical fiber sensors, linearly polarized optical waves are input to the optical fiber. The linear polarization can be expressed mathematically as a superposition of two circular polarizations (right-hand and left-hand). The magnetic field induced around a current carrying element induces a circular birefringence inside the optical fiber coil. Hence, after passing through the coil, a relative phase difference between two circular polarization components is generated, which results in the rotation of the linear polarization angle in proportion to the enclosed current and the number of fiber turns.

rotate the polarization of the light passing through the fiber. The output polarization is measured using a polarization measurement system and the results are transmitted to a personal computer.

In current calculations, the magnetic field inside the solenoid is assumed to be constant. This approximation is true in the case of an infinitely long solenoid. However, the solenoid, which is used in MO sensors, has a finite length. As a result, this might lead to a discrepancy between the theory and the measurement. The purpose of this work is to show this discrepancy for the short solenoid. The next Section 2 is dedicated to review Faraday rotation. Section 3 introduces the system and Section 4 represents the main principles of the MO sensors. A summary and conclusion is given in Section 5.

The Faraday effect describes the rotation if the plane of polarization of a light wave as it propagates through a medium subjected to a magnetic field parallel to the direction of propagation of the light. The Faraday effect in single mode fibers permits a fast response for current sensing on hight-voltage transmission lines if sufficiently long fibers can be used [8-10]. In an ideal nonbirefringent fiber of length L_{F}, wound in N_{F} turns of radius r around a conductor carrying a current I, the Faraday effect will rotate the plane of polarization for an incident linearly polaized light beam through an angle θ_{F} which is proportional to the magnetic field strength, and the Verdet constant V.

The Verdet constant can be utilized as an indicator for the suitability of a magnetic material for its use as Faraday rotator. It is defined as the rotation per unit path, per unit field strength [

The magnetic field strength induced by an electrical current in a conductor can be calculated by the BiotSavart law

where μ_{0} is permeability of vacuum, l_{c} is the length element of the conductor, and r the displacement vector from the element to the field point.

The configuration we have is that the fiber is passing along the axis of a solenoid, named the z-axis. The solenoid have length L_{S} and N_{S} turns of radius R. The center of the coordinate axis is chosen to be the center of the solenoid. The magnetic field strength is calculated at a point (X, 0, Z) from the solenoid center to be

where N_{S} is defined as the length of the solenoid L_{S} divided by the thickness of the constructing wire of the solenoid W_{S},

and

In the calculation of the magnetic field the y component is equal to zero due to the symmetry of the problem.

Equation (3) can be formulated in terms of Elliptic functions E(m) and K(m)

where

and m is

The sensitivity S = dθ/dI is calculated as follows,

In Equation (11) the length of the fiber is limited by the length of the solenoid. Here the length of the solenoid is introduced as a variable such that we can calculate the sensitivity for different solenoids’ lengths.

In this section, we consider a special case where the fiber is passing through the center of the solenoid. In this case the magnetic field at a point along the z axis can simply calculated from Equation (3) or Equation (7) by simply define X = 0

(13)

Equation (13) is simplified for a very long solenoid to be

The sensitivity can be calculated from Equations (11) and (12) yielding

while the approximated sensitivity S_{a} as calculated using Equation (14) is

function of the length of the solenoid. In

The effect of an inhomogeneous magnetic field on the sensitivity of an optical current sensor is studied in this work. The sensor consists of an optical fiber situated at the longitudinal axis of the solenoid. The results show that the sensitivity as calculated from exact calculation of the magnetic field differs from the sensitivity calculated using an approximate calculation of the magnetic field for short solenoids. For long solenoids the two values coincides.