Inverse scattering theory for optical waveguides and devices: Synthesis from rational and nonrational reflection coefficients

Jordan, Arthur K.; Tamil, Lakshman S.

doi:10.1029/96rs02501

Cited by 2 publications

(2 citation statements)

References 16 publications

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“…However, even in the numerical case the concepts from the inverse scattering theory are still useful. 26 An important point to note is that K͑s, t͒ is not a function of k, and so if we solve Eq. ͑12͒ for K͑s, t͒, we can obtain the solution of the inverse problem straight from Eq.…”

Section: Reconstruction Of the Refractive-index Profilementioning

confidence: 99%

Dispersive mirror in AlGaAs designed by inverse spectral theory

Dods

Ogura

1997

Appl. Opt.

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We introduce a new mathematical method, based on the inverse spectral theory of Gel'fand and Levitan, of designing dispersive coatings for use in femtosecond lasers. We fabricated an example in AlGaAs by metal-organic chemical-vapor deposition. The mirror has a high value of group delay dispersion over a bandwidth of 10 nm, reaching an extreme of -1200 fs(2) at the center (805 nm) and falling to -800 fs(2) at the edge of this range. In the same band the reflectivity remains over 95%. We created the design by identifying parameters in the spectral domain, numerically optimizing these parameters, and solving the resulting inverse problem to recover the refractive-index profile. Because we performed the optimization in the spectral domain, we needed only four parameters to obtain a good result. Numerical analysis shows that the excess optical delay at the red end of the stop band can be achieved by use of a mild optical resonance, with the optical field approximately twice the magnitude of that at the blue end.

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Section: Reconstruction Of the Refractive-index Profilementioning

confidence: 99%

Dispersive mirror in AlGaAs designed by inverse spectral theory

Dods

Ogura

1997

Appl. Opt.

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“…Random acoustic waveguides with finite cross-section are considered in [4,11], and with unbounded cross-section, as encountered in ocean acoustics, in [3,21]. Examples of inverse scattering problems in planar electromagnetic waveguides are in [13,17,22], where the problem is reduced to one for the scalar Helmholtz equation by considering a single type of waves, transverse electric or magnetic.…”

mentioning

confidence: 99%

Imaging with electromagnetic waves in terminating waveguides

Borcea¹,

Nguyen²

2016

IPI

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We study an inverse scattering problem for Maxwell's equations in terminating waveguides, where localized reflectors are to be imaged using a remote array of sensors. The array probes the waveguide with waves and measures the scattered returns. The mathematical formulation of the inverse scattering problem is based on the electromagnetic Lippmann-Schwinger integral equation and an explicit calculation of the Green tensor. The image formation is carried with reverse time migration and with ℓ 1 optimization.

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Inverse scattering theory for optical waveguides and devices: Synthesis from rational and nonrational reflection coefficients

Cited by 2 publications

References 16 publications

Dispersive mirror in AlGaAs designed by inverse spectral theory

Dispersive mirror in AlGaAs designed by inverse spectral theory

Imaging with electromagnetic waves in terminating waveguides

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