Kyle J. Daun scite author profile

We present a method based on Tikhonov regularization for solving one-dimensional inverse tomography problems that arise in combustion applications. In this technique, Tikhonov regularization transforms the ill-conditioned set of equations generated by onion-peeling deconvolution into a well-conditioned set that is less susceptible to measurement errors that arise in experimental settings. The performance of this method is compared to that of onion-peeling and Abel three-point deconvolution by solving for a known field variable distribution from projected data contaminated with an artificially generated error. The results show that Tikhonov deconvolution provides a more accurate field distribution than onion-peeling and Abel three-point deconvolution and is more stable than the other two methods as the distance between projected data points decreases.

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Time-resolved laser-induced incandescence characterization of metal nanoparticles

Sipkens

Singh

Daun

2016

Appl. Phys. B

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Infrared species limited data tomography through Tikhonov reconstruction

Daun

2010

Journal of Quantitative Spectroscopy and Radiative Transfer

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Parameter selection methods for axisymmetric flame tomography through Tikhonov regularization

Åkesson¹,

Daun

2008

Appl. Opt.

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Deconvolution of optically collected axisymmetric flame data is equivalent to solving an ill-posed problem subject to severe error amplification. Tikhonov regularization has recently been shown to be well suited for stabilizing this deconvolution, although the success of this method hinges on choosing a suitable regularization parameter. Incorporating a parameter selection scheme transforms this technique into a reliable automatic algorithm that outperforms unregularized deconvolution of a smoothed data set, which is currently the most popular way to analyze axisymmetric data. We review the discrepancy principle, L-curve curvature, and generalized cross-validation parameter selection schemes and conclude that the L-curve curvature algorithm is best suited to this problem.

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Chemical species tomography of turbulent flows: Discrete ill-posed and rank deficient problems and the use of prior information

Daun

Grauer

Hadwin

2016

Journal of Quantitative Spectroscopy and Radiative Transfer

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Instantaneous 3D flame imaging by background-oriented schlieren tomography

Grauer

Unterberger

Rittler

et al. 2018

Combustion and Flame

102

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Kyle J. Daun

Thermal Radiation Heat Transfer

Heat conduction from a spherical nano-particle: status of modeling heat conduction in laser-induced incandescence

Deconvolution of axisymmetric flame properties using Tikhonov regularization

Time-resolved laser-induced incandescence characterization of metal nanoparticles

Infrared species limited data tomography through Tikhonov reconstruction

Parameter selection methods for axisymmetric flame tomography through Tikhonov regularization

Chemical species tomography of turbulent flows: Discrete ill-posed and rank deficient problems and the use of prior information

Instantaneous 3D flame imaging by background-oriented schlieren tomography

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