@techreport{f667cacd0d0f4a72908a928a8e6c2e5f,
title = "Diffusive tomography methods: special boundary conditions and characterization of inclusions",
keywords = "diffusion approximation, electrical impedance tomography, electrode models, factorization method, inclusions, inverse boundary value problems, inverse conductivity problem, non-scattering regions, optical tomography, radiative transfer equation, variational principles, diffusion approximation, electrical impedance tomography, electrode models, factorization method, inclusions, inverse boundary value problems, inverse conductivity problem, non-scattering regions, optical tomography, radiative transfer equation, variational principles, diffusion approximation, electrical impedance tomography, electrode models, factorization method, inclusions, inverse boundary value problems, inverse conductivity problem, non-scattering regions, optical tomography, radiative transfer equation, variational principles",
author = "Nuutti Hyv{\"o}nen",
year = "2004",
language = "English",
isbn = "951-22-7068-4",
series = "Helsinki University of Technology Institute of Mathematics Research Reports",
publisher = "TKK",
number = "A471",
type = "WorkingPaper",
institution = "TKK",
}