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Inverse Problems in Science and Engineering Volume 24, 2016 - Issue 6
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Articles

Inverse design of anti-reflection coatings using the nonlinear approximate inverse

Mohammad Alakel AbazidFaculty of Mathematics and Computer Science, Institute of Applied Mathematics, Saarland University, Saarbrücken, Germany.
,
Aref LakhalFaculty of Mathematics and Computer Science, Institute of Applied Mathematics, Saarland University, Saarbrücken, Germany.
&
Alfred K. LouisFaculty of Mathematics and Computer Science, Institute of Applied Mathematics, Saarland University, Saarbrücken, Germany.Correspondence[email protected]
Pages 917-935 | Received 12 Nov 2014, Accepted 25 Jul 2015, Published online: 09 Oct 2015

References

  • Chen CJ. Physics of solar energy. Hoboken (NJ): Wiley; 2011.
  • Chen D. Anti-reflection (AR) coatings made by sol--gel process. Sol. Energy Mater. Sol. Cells. 2001;68:365–391.
  • Bao G, Wang Y. Optimal design of antireflection coatings with different metrics. J. Opt. Soc. Am. A. 2013;30:656–662.
  • Dimitriev VI, Chernyavskii AS. Integral characteristic method in the inverse problem of optical coating design. Comput. Math. Model. 2001;12:128–136.
  • Nubile P. Analytical design of antireflection coatings for silicon photovoltaic devices. Thin Solid Films. 1999;342:257–261.
  • Lesnic D. Determination of the index of refraction of anti-reflection coatings. Math-in-Ind. Case Stud. J. 2010;2:155–173.
  • Mahdjoub A, Zighed L. New designs for graded refractive index antireflection coatings. Thin Solid Films. 2005;478:299–304.
  • Alakel Abazid M, Lakhal A, Louis AK. Non-destructive testing of anti-reflection coatings for solar cells. In: Proceedings of the European Workshop on Renewable Energy Systems (EWRES). Antalya, Turkey; 2013. pp. 24–28.
  • Alakel Abazid M, Lakhal A, Louis AK. A stable numerical algorithm for the design of anti-reflection coatings for solar cells. Int. J. Renew. Technol. in press.
  • Janicki V, Sancho-Parramon J, Zorc H. Refractive index profile modelling of dielectric inhomogeneous coatings using effective medium theories. Thin Solid Films. 2008;516:3368–3373.
  • Hagin F. Some numerical approaches to solving one-dimensional inverse problems. J. Comput. Phys. 1981;43:16–30.
  • Belai OV, Frumin LL, Podivilov EV, Shapiro DA. Inverse scattering for the one- dimensional Helmholtz equation: fast numerical method. Opt. Lett. 2008;33:2101–2103.
  • Sacks P. An inverse problem in coupled mode theory. J. Math. Phys. 2004;45:1699–1710.
  • Chen Y, Rokhlin V. On the inverse scattering problem for the Helmholtz equation in one dimension. Inverse Prob. 1992;8:365-391.
  • Dunn MH, Hariharan SI. Numerical computations on one-dimensional inverse scattering problems. NASA Contractor Rep. 1984;55:157-165.
  • Beilina L, Klibanov M. Reconstruction of dielectrics from experimental data via a hybrid globally convergent/adaptive inverse algorithm. Inverse Prob. 2010;26:125009.
  • Beilina L, Nguyen TT, Klibanov M and Malmberg JB. Reconstruction of shapes and refractive indices from backscattering experimental data using the adaptivity. Inverse Prob. 2014;30:105007.
  • Li J, Xi J, Zou J. An adaptive finite element reconstruction of distributed fluxes. Inverse Prob. 2011;27: 075009 (25pp).
  • Born M, Wolf E. Principle of optics. 7th ed. Cambridge (UK): Cambridge University Press; 1999.
  • Kak AC, Slaney M. Principles of computerized tomographic imaging. New York (NY): IEEE Press; 1988.
  • Natterer F. An error bound for the Born approximation. Inverse Prob. 2004;20:447-452.
  • Lakhal A, Louis AK. Locating radiating sources for Maxwell’s equations using the approximate inverse. Inverse Prob. 2008;24: 045020 (18pp).
  • Lakhal A. A decoupling-based imaging method for inverse medium scattering for Maxwell’s equations. Inverse Prob. 2010;26:015007.
  • Lakhal A. KAIRUAIN-algorithm applied on electromagnetic imaging. Inverse Prob. 2013;29: 095001 (18pp).
  • Louis AK. Inverse und schlecht gestellte Probleme [Inverse and ill-posed problems]. Stuttgart: Teubner; 1989.
  • Louis AK. A unified approach to regularization methods for linear ill-posed problems. Inverse Prob. 1999;15:489–498.
  • Louis AK, Maass P. A mollifier method for linear operator equations of the first kind. Inverse Prob. 1990;6:427–440.
  • Louis AK. Approximate inverse for linear and some nonlinear problems. Inverse Prob. 1996;12:175-190.
  • Louis AK. Constructing an Approximate Inverse for Linear and Some Nonlinear Problems in Engineering. In: Delaunay D, Jarug Y, Woodbury KA, editors. Inverse Problems in Engineering - Theory and Practice. New York (NY): The American society of Mechanical Engineers; 1998. 367–374.
  • Colton D, Kress R. Inverse acoustic and electromagnetic scattering theory. 2nd ed. Berlin: Springer Verlag; 1998.
  • Louis AK. Combining image reconstruction and image analysis with an application to two-dimensional tomography. SIAM J. Imag. Sci. 2008;1:188–208.
  • Louis AK. Feature reconstruction in inverse problems. Inverse Prob. 2011;27: 065010 (21pp).
  • Kohr H. A linear regularization scheme for inverse problems with unbounded linear operators on Banach spaces. Inverse Prob. 2013;29:065015.
  • Schuster T, Schöpfer F. Solving linear operator equations in Banach spaces non-iteratively by the method of approximate inverse. Inverse Prob. 2010;26:085006.
  • Hahn B, Louis AK. Reconstruction in the three-dimensional parallel scanning geometry with application in synchrotron-based x-ray tomography. Inverse Prob. 2012;28:045013.
  • Arridge S, Schotland JC. Topical review: optical tomography: forward and inverse problems. Inverse Prob. 2009;25:123010.
  • Jost R. Construction of a potenetial from a phase shift. Phys. Rev. 1952;87.
  • Moses HE. Calculating of the scattering potential from reflection coefficients. Phys. Rev. 1956;102:559–567.
  • Snieder R. An extension of Backus--Gilbert theory to nonlinear inverse problems. Inverse Prob. 1991;7:409–433.
  • Snieder R. The role of nonlinearity in inverse problems. Inverse Prob. 1998;14:387–404.
  • Markel VA, O’Sullivan JA, Schotland JC. Inverse problem in optical diffusion tomography. IV. Nonlinear inversion formulas. J. Opt. Soc. Am. A. 2003;20:903–912.
  • Moskow S, Schotland JC. Numerical studies of the inverse Born series for diffuse waves. Inverse Prob. 2009;25:095007.

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