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Fabrication and Mode Coupling of Long-Period Fiber Grating by Winding a Wire Around an Optical Fiber Fixed to a Cylindrical Metal Rod

Written By

Jonghun Lee, Cherl-Hee Lee, Kwang Taek Kim and Jaehee Park

Submitted: 03 July 2012 Published: 15 May 2013

DOI: 10.5772/53069

From the Edited Volume

Current Trends in Short- and Long-period Fiber Gratings

Edited by Christian Cuadrado-Laborde

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1. Introduction

A long-period fiber grating (LPFG) couple light from the fundamental guided core mode to co-propagating cladding modes at specific resonance wavelengths. A LPFG can be fabricated by induction of periodic modulations of the refractive index along the core of a single-mode optical fiber. The pitch of a typical LPFG ranges from 100 μm to 1000 μm, which is larger than that of a fiber Bragg gratings (FBGs) by more than two orders of magnitude. The transmission spectrum of a LPFG consists of a number of rejection bands at the resonance wavelengths, like as a band-rejection filter. LPFGs were first proposed and demonstrated by Vengsarkar and others [1] as band-rejection filters, due to their high sensitivity as well as low insertion loss and return loss, LPFGs are becoming more and more popular as simple and versatile optical components for mode converters [2], gain flattening filters [3], and fiber-optic sensors [4]. Many methods have been demonstrated for the fabrication of LPFGs. An ultra-violet (UV) writing method, which causes the index change of a photosensitive Ge-doped silica fiber core by UV light radiation, was successfully applied to the writing of LPFGs [5]. The amount of index change depends on the intensity and the duration of the UV laser. Because of the symmetrically-formed index modulation in the core, only axially symmetric cladding modes are coupled in a UV-written LPFG. Many non-UV methods have also been demonstrated for the fabrication of LPFGs, such as the electric-discharge writing method [6], divided coil heaters method [7], microbending method [8-9], and mechanically induced method [10-11-12]. However, all of these methods involve expensive fabrication equipments or additional fixed devices, thereby increasing the installation costs. Thus, the inexpensive manufacture of small LPFGs has been major barrier for the realization of practical optical communication systems. Recently, winding wires has been presented as a new fabrication method to form LPFGs on an optical fiber [13-14]. In [13,14], since the coupling wavelength of the grating is defined by the period of the v-grooved tube, this requires very difficult and delicate fabrication operations. Thus, a new simple and flexible fabrication process was presented for the fabrication of low-cost LPFGs that does not require any formation of periodic grooves [15]. The wire-winding long-period fiber grating (WW-LPFG) presented in [15] is based on the periodic winding of a wire around an optical fiber attached to a cylindrical metal rod without any grooves. The periodic pressure from the winding wire on an optical fiber creates a periodic change in the refractive index of the optical fiber core, and makes mechanically-induced LPFGs on the optical fiber. A fabricated WW-LPFG with high tension of the winding wire on the optical fiber induces a high index variation on the fiber core. Thus, the coupling coefficient of the WW-LPFG was calculated according to the refractive index variation of the fiber core. The new approach is presented for the easy fabrication of wire-winding long-period gratings (WW-LPFGs) based on the periodic winding a wire around an optical fiber attached to a cylindrical rod. The periodic pressure of the wire induces change of the refractive index of the optical fiber core; thus, resonance wavelengths of the grating can be easily controlled according to the winding-wire pitch controlled by a microprocessor. At the winding-wire pitch of 500 μm, the spectra show resonance-wavelength dips corresponding to the LP02, LP03, LP04, and LP05 cladding modes; the resonance wavelengths go to longer wavelengths at the increased the winding pitch of 510 μm. These are in good agreement with theoretical values. The polarization dependence of a resonance wavelength shift of 9 nm and transmission power difference of 2.5 dB was shown at the 520 μm grating pitch. When the diameter of the cylindrical metal rod was smaller, or higher tension from the winding pressure was applied, stronger mode coupling resulted in deeper dips in the transmission spectra according to the induced higher index variation.

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2. Properties of long-period fiber grating

2.1. Effective index

The electric field in a cylindrical coordinate system has three independent vector components as a function of r, ϕ, and z:

E(r,ϕ,z)=r^Er(r,ϕ,z)+ϕ^Eϕ(r,ϕ,z)+z^Ez(r,ϕ,z).E1

Unlike the Er and Eϕ component, the Ez component does not couple to the other components of Er and Eϕ; therefore, the scalar wave equation for Ez can exist independently and easily be solved. Thus, the other fields, Er and Eϕ, are derived easily through the calculated Ez component. The wave equation for the z component of the field vectors is given as follows in the homogeneous region:

(2+k2){EzHz}=0,E2

where k22με and ∇2 is the Laplacian operator in the cylindrical coordinate given by

2=2r2+1rr+1r22ϕ2+2z2,E3

Every component of the fields, including Ez, is assumed to have the angular frequency ω and the wavenumber of β to the longitudinal direction z-axis, and Eqn. (2) can be written as

2Ezr2+1rEzr+1r22Ezϕ2+[k2n(r,ϕ)2β2]Ez=02Hzr2+1rHzr+1r22Hzϕ2+[k2n(r,ϕ)2β2]Hz=0,E4

where n(r,ϕ) is the refractive index of an optical fiber at the transverse axis. Here, Ez and Hz can be expressed with the form of the Bessel differential function of order l, l =0,1,2,3,..., so Ez and Hz are single-valued function of ϕ:

Ez={AJl(κr)ejlϕejβz,(0ra)CKl(γr)ejlϕejβz,(r>a)Hz={BJl(κr)ejlϕejβz,(0ra)DKl(γr)ejlϕejβz,(r>a)E5

At Maxwell’s curl equations, Eqn. (6), the transverse electromagnetic fields are related to Ez and Hz:

×E=jωμH,×H=jωεE,E6

Substituing Eqn. (5) to Eqn. (6), all the transverse components are obtained as follows:

At the core region (r<a):

Er=jβκ2[AκJl'(κr)+BjωμlβrJj(κr)]ejlϕejβzEϕ=jβκ2[AjlrJl(κr)BωμβκJl'(κr)]ejlϕejβzHr=jβκ2[AjωεcolβrJl(κr)+BκJl'(κr)]ejlϕejβzHϕ=jβκ2[AωεcoβκJl'(κr)+BjlrJl(κr)]ejlϕejβzE7

At the cladding region (r>a):

Er=jβγ2[CγKl'(γr)+DjωμlβrKj(γr)]ejlϕejβzEϕ=jβγ2[CjlrKl(γr)DωμβγKl'(γr)]ejlϕejβzHr=jβγ2[CjωεcllβrKl(γr)+DγKl'(γr)]ejlϕejβzHϕ=jβγ2[CωεclβγKl'(γr)+DjlrKl(γr)]ejlϕejβzE8

where εco0nco2, εcl0ncl2, and

Jl'(κr)=dJl(κr)d(κr),Kl'(γr)=dKl(γr)d(γr),E9

The boundary condition that Ez and Hz should be continuous at r=a leads to

C=AJl(κa)Kl(γa),D=BJl(κa)Kl(γa).E10

The boundary condition that Eϕ should be continuous at r=a leads to

Ajla(1κ2+1γ2)=Bωμβ[1κJl'(κa)Jl(κa)+1γKl'(γa)Kl(γa)].E11

The boundary condition that Hϕ should be continuous at r=a leads to

A[ωεcoβ1κJl'(κa)Jl(κa)+ωεclβ1γKl'(γa)Kl(γa)]=Bjla(1κ2+1γ2).E12

Equation (11) and (12) yield the following equation determining the effective index and propagation constant:

β2l2a2(1κ2+1γ2)2=(1κJl'(κa)Jl(κa)+1γKl'(γa)Kl(γa))(k02nco21κJl'(κa)Jl(κa)+k02ncl21γKl'(γa)Kl(γa)).E13

If weakly guiding condition, nconcl, Eqn. (13) is simplified to

neff2l2a2(1κ2+1γ2)2=(1κJl'(κa)Jl(κa)+1γKl'(γa)Kl(γa)).2E14

By using the Bessel function identity,

Jl'(κa)κJl(κa)=±Jl1(κa)κJl(κa)lκ2,Kl'(γa)γKl(γa)=Kl1(γa)γKl(γa)lγ2,E15

we can get

(±Jl1(κa)κaJl(κa)l(ka)2)+(Kl1γaKll(γa)2)=±l[1(κa)2+1(γa)2].E16

From Eqn. (16) two different equations corresponding to the two values of +l,-l are obtained and the eigenvalues resulting from these two equations yield the two classes of solutions designated as the EH modes and HE modes. The characteristic equations of the EH and HE modes correspond to the upper sign and the lower sign, respectively.

For EH mode:

1κaJl+1(κa)Jl(κa)=1γaKl+1(γa)Kl(γa)E17

For HE mode:

1κaJ0(κa)J1(κa)=1γaK0(γa)K1(γa),(l=1)1κaJl1(κa)Jl2(κa)=1γaKl1(γa)Kl2(γa),(l2)E18

Some characteristic equations among the TE, TM, EH, and HE modes are the same under the weakly guiding approximation, and the degenerate modes are classified as approximated linear polized (LPlm) modes:

1κaJl(κa)Jl1(κa)=1γaKl(γa)Kl1(γa).E19

Figure 1 shows a graphical determination of the effective index of LP01 core mode and Fig. 2 shows the mode intensity of LP01 core mode. The cladding modes can be obtained by applying the boundary continuity conditions at the core-cladding boundary and the cladding-air boundary. Erdogan [16] proposed an accurate description of the mode propagation in the cladding, in which the cladding modes are not approximated as being linearly polarized. Applying the core-cladding boundary condition, the characteristic equation for a cladding mode was given by

ζ0=ζ0'E20
ζ0=1σ2u2(JK+σ1σ2u21u32n22a1a2)pl(a2)Kql(a2)+Jrl(a2)1u2sl(a2)u2(u32n22a2Ju21n12a1K)pl(a2)+u32n12a2ql(a2)+u21n12a1rl(a2)E21
ζ0'=σ1u2(u32a2Jn32u21n22a1K)pl(a2)+u32a2ql(a2)+u21a1rl(a2)u2(n32n22JK+σ1σ2u21u32n12a1a2)pl(a2)n32n12Kql(a2)+Jrl(a2)n22n12u2sl(a2)E22

Figure 1.

Graphical determination of the effective index of core mode.

Figure 3 shows the graphical determination of the effective indice of cladding modes according to Eqn. (20), which are determined by the crossing points of the left-hand side equation and the right-hand side equation.

Figure 2.

Mode intensity distribution of LP01 core mode

Figure 3.

Graphical determination of the effective index of cladding modes.

2.2. Coupling coefficient

The transverse electric fields are described by a linear superposition of forward-propagating and backward-propagating guided modes of the unperturbed optical fiber:

E(x,y,z)=[A+(z)ejβz+A(z)ejβz]et(x,y),E23

where A+(z) and A-(z) are slowly varying amplitudes traveling in the +z and –z directions, respectively; β is the propagation constant; and et(x,y) is the transverse mode field. The mode coupling of the electric field occurs at the gratings of the optical fiber core, which acts as a perturbation in the refractive index. Thus, the coupled mode equation can be written as

dA+dz=jA+Kej(β+β+)zjAKej(β++β)zdAdz=jA+Kej(β++β)z+jAKej(ββ)zE24

where K(z), the general transverse coupling coefficient between modes, is given

K(z)=ω4Δε(x,y,z)et(x,y)et*(x,y)dxdy=ω4{2ncoδnco[1+νcos(2πΛz+ϕ)]}et(x,y)et*(x,y)dxdy=ωnco2δncoet(x,y)et*(x,y)dxdy+ωnco2ν22cos(2πΛz+ϕ)et(x,y)et*(x,y)dxdy=ωnco2δncoet(x,y)et*(x,y)dxdy+ν2[ωnco2et(x,y)et*(x,y)dxdy][2cos(2πΛz+ϕ)]=σ(z)+[ν2σ(z)][2cos(2πΛz+ϕ)]=σ(z)+κ[2cos(2πΛz+ϕ)]E25

where Δε is the permittivity variation of a fiber core and ν is the fringe visibility associated with the index change. When two new coefficients are defined,

σ(z)=ωnco2δn¯coet(x,y)et*(x,y)dxdyκ(z)=ωncoν4δn¯coΔε(x,y,z)et(x,y)et*(x,y)dxdy,E26

where σ is a dc coupling coefficient and κ is an ac coupling coefficient. By substituting Eqn. (25),(26) to Eqn. (24), the electric fields in the grating can be simplified to the superposition of forward-propagating and backward-propagating fundamental modes in the optical fiber core:

dR(z)dz=iσ^(z)R(z)+iκ(z)S(z)dS(z)dz=iσ^(z)S(z)iκ*(z)R(z),E27

where R(z)=A+(z)exp[i(δz-ϕ/2)] and S(z)=A-(z)exp[-i(δz+ϕ/2)]. The general dc self-coupling coefficient can be represented by

σ^=δ+σ12dϕdz=(βπΛ)+σ12dϕdz,E28

where δ is the detuning factor, the ϕ and dϕ/dz are the grating phase and possible chirp of the grating period, respectively. The solution of the complex reflection and transmission coefficient can be

R(z)=γcosh[γ(zL/2)]+iσ^sinh[γ(zL/2)]γcosh(γL)iσ^sinh(γL)S(z)=iκsinh[γ(zL/2)]γcosh(γL)iσ^sinh(γL)                           ,E29

where γ is described by

γ=κ2σ^2, (if, κ2>σ^2)γ=iσ^2κ2, (if, κ2<σ^2).E30

The amplitude reflection coefficients can then be shown to be

ρ=S(L/2)R(L/2)=κsinh(γL)σ^sinh(γL)+γcosh(γL).E31
(31)

2.3. Resonance wavelength

With the knowledge of the core and cladding effective indices, it is possible to determine LPFG resonance wavelengths for a specific grating period. This can be achieved by the phase matching condition in [16]. The transmission spectrum has dips at the wavelengths corresponding to resonances with various cladding modes. The resonance wavelength satisfying the phase-matching condition is given by [17]

λ0=(neff,co01neff,cl0m)Λ,E32

where Λ is the period of the grating, and neff,co01and neff,cl0m are the effective indices of the LP01 core mode and LP0m cladding modes at the resonance wavelength, respectively. Based on the phase-matched condition, the relationship between the period of the grating period (Λ) and resonance wavelength (λ0) can be obtained by the calculation of the propagation constants of the LP01 core and various cladding modes of a fiber at each specific wavelength. Figure 4 shows the resonance wavelength versus grating period characteristic for coupling with five orders of cladding modes, and for a specific grating pitch the spectrum yields resonance wavelength values for all visible bands.

Figure 4.

Resonance wavelength versus grating period.

Coupling mode theory applied to the three-layer model yields an expression for the core-cladding mode coupling coefficient by Erdogan [16]. The transmission spectrum modelled as Λ=455μm, L=20mm, and Δnco=1×10-4 is shown in Fig. 5.

Figure 5.

Transmission spectrum

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3. Experiments and results

A LPFG has coupling characterisitics according to the phase-matching condition between a core mode and cladding modes in an optical fiber. A forward-propagating core mode (LP01 mode) is coupled to forward-propagating cladding modes (LPlm mode) of the fiber. While LPFG generally allows coupling of a core mode to all order cladding modes (LPlm mode), untilted WW-LPFG couples a core mode to only l=0 order cladding modes (LP0m mode). The proposed WW-LPFG behaving as an un-tilted LPFG couples a core mode to LP0m modes.

Figure 6 shows the structure and photo of the manufactured WW-LPFG. The SMF-28 standard fiber with a numerical aperture (NA) of 0.14, refractive index difference of 0.36 %, core and cladding diameters of 8.2 and 125 μm, respectively, was used. The refractive indices of core and cladding were 1.4489 and 1.444, respectively, at a 1550 nm wavelength. A copper wire with the diameter of 170 μm was used as a winding wire. The jacket of a SMF was stripped away to allow a copper wire to be wound around the fiber. The SMF was then attached to a cylindrical metal rod with a 10 mm diameter.

Figure 7 shows the apparatus and manufacturing process to fabricate the WW-LPFG. After an optical fiber was attached to the cylindrical metal rod, one end of a copper wire was glued to the cylindrical metal rod, and the other end of the copper wire was pulled by the mass of 900 g weight at the angle (θ) of 60 º, convertible to the tension of 8.8 N. When the cylindrical metal rod was rotated by a microprocessor, the wire holder controlled by a microprocessor is moved to the longitudinal direction of the cylindrical metal rod according to the designed pitch, so that the optical fiber was wound by the wire within the desired region. The lateral stress of the wire periodically pressing on the optical fiber changes the refractive index of the optical fiber, so the pitch of the winding wire is the key factor to the controlling of the resonance wavelength of the WW-LPFG. The experimental setup consisted of a broadband light source (Agilent, 83437A), the fabricated WW-LPFG, and an optical spectrum analyzer (Ando, AQ6315A). The light from the broadband light source propagated in the WW-LPFG, and the power intensity characteristics of the transmitted light were then determined when it reached the OSA.

Figure 8 shows the relationship of resonance wavelength with the grating period for the coupling of fundamental core mode to cladding modes. The transmission spectrum has dips at the wavelengths corresponding to resonances with various cladding modes. The resonance wavelength satisfying the phase-matching condition is given by Eqn. (32). Based on the phase-matched condition, the relationship between the period of the grating period and the resonance wavelength can be obtained by the calculation of the propagation constants of the LP01 core and various cladding modes of a fiber at each specific wavelength. Resonance wavelengths where guided-to-cladding mode coupling takes place can be theoretically determined by proper selection of a specific grating period. The vertical dashed line at the grating period of 500 μm meets with the wavelengths of 1280 nm, 1330 nm, 1380 nm, and 1490 nm of LP02, LP03, LP04, LP05 modes, respectively. The resonance wavelengths of LP02, LP03, LP04, LP05 modes correspond to 1280 nm, 1330 nm, 1380 nm, and 1490 nm, respectively. The parameters of the winding pitch, number of turns, and winding length of the copper wire are 500 μm, 40 turns, and 20 mm, respectively. Figure 9 shows the experimental and simulated transmission spectra of the WW-LPFG under the same conditions as those in Fig. 8. The simulated transmission spectra calculated by simulation software, OptiGrating (Optiwave Systems Inc) were in good agreement with the experimental result at the resonance wavelengths and transmission power loss. At 1490 nm, the transmission power gain of the resonance wavelength was -7.7 dB and the full width at half maximum (FWHM) was 20 nm.

Figure 6.

Structure of the WW-LPFG.

Figure 7.

Experimental setup and apparatus

Figure 8.

Resonance wavelength versus grating period.

Figure 9.

Transmission spectrum at the grating pitch of 500um

The spectral dependence of the power transmission of the LP01 mode in the LPFG can be determined by [16]

P01(L)P01(0)=cos2(κ2+δ2L)+11+κ2δ2sin2(κ2+δ2L),E33

where δis the detuning parameter

δ=12{βco01βcl0m2πΛ},E34

κ is the coupling constant for the grating, L is the grating length, and βco01and βcl0m are the propagation constants of the LP01 core mode and LP0m cladding modes, respectively. The standard silica optical fiber is a cylindrical and isotropic dielectric waveguide with a circularly symmetric refractive index distribution. However, as the applied tension of the wire induces deformations of the optical fiber, the refractive indices parallel and perpendicular to the direction of the applied tension are differently changed and the birefringence is derived from the photo-elastic property of the fiber. The refractive index changes at any point of the fiber are [18]

for x-polarization,

(Δneff)x=12(neff,0)3[P11εx+P12(εy+εz)],E35

for y-polarization,

(Δneff)y=12(neff,0)3[P11εy+P12(εx+εz)].E36

Here, neff,0 is the initial effective refractive index of the core of unperturbed fiber, P11 and P12 are the photo-elastic coefficients of the unperturbed optical fiber, and εx, εy, εz are the strain components at the fiber in the x, y, and z direction, respectively. Because of the mechanical and photo-elastic properties of the optical fiber’s material (P11<P12, εx>0, εy<0, εx< εy), the refractive index change of the x-polarization is higher than that of the y-polarization. Since the circular fiber of the fabricated WW-LPFG is periodically pressed in one direction to form a mechanically induced long-period grating, birefringence due to the asymmetric structure occurs.

As shown in Fig. 10, the spectrum of the fabricated WW-LPFG has polarization dependence on x- and y-polarization lights. When an LP01 core mode is coupled to an LP04 cladding mode at a 520 μm grating pitch, the resonant wavelengths of x- and y-polarization light appeared at 1435 and 1426 nm, respectively. By the birefringence effect, the polarization dependence makes the change of 9 nm resonance wavelength and 2.5 dB transmitted light power. Figure 11 shows the transmission spectra of the LP04 mode of the WW-LPFG with the pitch of 500 μm and with several masses of 0.6, 0.9, and 1.2 kg weight, convertible to the tension of 5.8, 8.8, and 11.7 N, respectively. The higher tension by the winding wire pressure induced the higher index variation, which resulted in stronger mode coupling and thus generally in deeper dips in the transmission spectra. Meanwhile, the resonant wavelength did not shift by the change of the applied tension.

The transmission spectra of the LP04 mode of the WW-LPFG with the diameters of the cylindrical metal rod of 7 and 10 mm were shown in Fig. 12 at the fixed pitch of 500 μm. When the diameter of the cylindrical metal rod is smaller, the pressing region on the fiber attached to the cylindrical metal rod is wider, and thus the higher index variation of the fiber results in deeper dips in the transmission spectrum.

Figure 10.

Polarization dependence of an LP04 mode at a grating pitch of 520um

Figure 11.

Transmission spectra of the WW-LPFG with different wire tensions.

Figure 12.

Transmission spectra of the WW-LPFG with different diameters of the cylindrical metal rod.

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4. Conclusion

An easily fabricated WW-LPFG is wire-wound periodically around an optical fiber attached to a cylindrical rod. The periodic pressure of the wire results in refractive index change of an optical fiber core, and the resonance wavelengths of the grating can be easily controlled according to the winding-wire pitch controlled by a microprocessor. Due to the simple and flexible fabrication process using the winding of a wire, the fabricated WW-LPFG is small, and cost-effective, and the resonance wavelength are easily controlled by the pitch of the winding-wire using a microprocessor. At the winding-wire pitch of 500 μm and 510 μm, the spectra show resonance-wavelength dips corresponding to the LP02, LP03, LP04, LP05 cladding modes. The polarization dependence of a resonance wavelength shift of 9 nm was shown. Smaller diameter of the cylindrical metal rod and higher tension of the winding wire led to the stronger mode coupling according to induced higher index variation. With smaller diameter of the cylindrical metal rod, or higher tension due to the winding pressure, stronger mode coupling can result in deeper dips in the transmission spectra according to induced higher index variation.

Acknowledgement

This work was supported by the DGIST R&D Program of the Ministry of Education, Science and Technology of Korea(12-RS-02).

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Written By

Jonghun Lee, Cherl-Hee Lee, Kwang Taek Kim and Jaehee Park

Submitted: 03 July 2012 Published: 15 May 2013