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CV
Table of Contents
{ Abstract / Résumé }
Chapter 1
Chapter 2
{ 3.1 }
3.2.1 : Overview of reconstruction methods
3.2.2 : Discrete Layer-peeling
Ph.D.  /  { Web Version }  /  Chapter 3  /  { 3.2 }  /  3.2.3 : Reconstructed FBG interpretation
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Chapter 4
Chapter 5
Chapter 6
Chapter 7
Chapter 8
Appendix
Other parts
3.3
{ 3.4 }
{ 3.5 }
3.6
3.7

3.2        FBG synthesis and reconstruction

3.2.3       Reconstructed FBG interpretation

The complex coupling coefficients qj are calculated from the complex reflectors rj through the equation (3-16a). The complex coupling coefficient distribution q(z) can then be calculated by interpolation between the positions j×D. The complex coupling coefficient gives the local grating strength and its chirp and is related to the three distributions Dnac(z), Dndc(z) and q(z) by the following equations :

(3-17a)


(3-17b)


(3-17c)

where fq = Arg(q) and k has been evaluated at the design wavelength (ld = 2 neff Ld). We can notice that a single reconstruction cannot distinguish a period chirp from a DC refractive index chirp. For this reason, an effective grating period Leff for each layer is defined, which represents the chirp function :

(3-18)

where Ld is the design period. The local Bragg wavelength corresponds to 2Leff×neff. The effective grating period can be expressed as a function of the Dndc and q distributions

(3-19)



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