1 / 12

Case and Inverse Problems Outline

Case and Inverse Problems Outline. Overview of inverse problems Ken’s early contributions for a localized source in an infinite media Ed Larsen and Chuck Siewert’s early breakthroughs for half-space and slab geometries

donny
Download Presentation

Case and Inverse Problems Outline

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Case and Inverse ProblemsOutline • Overview of inverse problems • Ken’s early contributions for a localized source in an infinite media • Ed Larsen and Chuck Siewert’s early breakthroughs for half-space and slab geometries • Azimuthal-angle-dependent slab geometry algorithms to determine anisotropic scattering coefficients

  2. Outline, cont. · Multigroup algorithms · Non-plane geometry algorithms Objective of talk:To convince you that even minor contributions by Case have led to many INVERSE transport publications

  3. Overview of inverse problems • Forward Problems: use properties of the medium, boundary conditions, and any sources to determine the angular flux • Inverse Problems: use the angular flux and or its angular moments to determine the properties of the medium, or boundary conditions, or any sources; often such problems are ill-conditioned

  4. Overview of inverse problems, cont. • Case’s analytical approach for solving inverse problems can be called an “explicit” method, in contrast to a traditional “implicit” method involving some sort of iterative technique, e.g., the method of steepest descent or conjugate gradient methods.

  5. Ken’s early contributions • Appendix H of Case and Zweifel’s 1967 monograph evaluates even-order spatially-integrated moments of the point- and plane-source densities due to a localized source in an infinite medium, as obtained by directly integrating the transport equation • In 1973 he introduced the phrase “inverse problem” into the transport theory literature while deriving analytical equations to determine the anisotropic scattering coefficients of the infinite medium from the spatially-integrated moments of the angular flux

  6. Ken’s early contributions, cont. • Kuščer and I in 1974 used spatial moments of the flux to directly relate the mth azimuthal Fourier moment of the flux to the mth Legendre coefficient of the scattering function • In 1975 Case made some additions to his 1973 paper for a localized source in an infinite medium • BUT LOCALIZED SOURCES IN INFINITE MEDIA ARE TOTALLY IMPRACTICAL FOR APPLICATIONS!

  7. Larsen and Siewert’s early half-space and slab geometry solutions • Larsen in 1975 derived a solution to determine the intensity and interior sources if the intensity at the surface of the half-space is known • Siewert in 1978 solved the multi-group problem for determining the properties of a slab from spatially-integrated moments inside the slab plus the angular moments of the emerging fluxes

  8. Larsen and Siewert’s early contributions, cont. • Siewert in 1978 solved for the mean number of secondaries of an isotropically-scattering half-space using only angular moments of the emerging angular flux • In 1979 Siewert published 3 papers extending his ideas to determine 3 coefficients for quadratically-anisotropic scattering

  9. Azimuthal-angle-dependent algorithms to determine anisotropic scattering coefficients • In 1979 I generalized Siewert’s slab-geometry equations to obtain two uncoupled sets of equations for determining—only in principle!—any number of anisotropic scattering coefficients • In 1981 Richard Sanchez and I obtained an even more general set of equations for determining the anisotropic scattering coefficients

  10. Multigroup algorithms • Larsen in 1981 derived a transport theory solution for obtaining multi-group cross sections from surface outgoing angular fluxes and ingoing adjoint angular fluxes from multiple experiments • Sanchez and I followed in 1983 to obtain the diffusion theory solution for multi-group cross sections and diffusion coefficients • Siewert and also Sanchez and I in 1983 obtained the scattering coefficients for polarized radiative transfer (which is somewhat analogous to multi-group transport)

  11. Non-plane geometry algorithms • In 1982 Siewert and Dunn solved the inverse problem for a variable illumination over the surface of a plane-parallel layer (e.g., for an incident searchlight illumination) • In 1984 Larsen formulated a solution to the time-dependent multi-group, homogeneous convex 3D medium for the scattering properties • In 2013 Machida at ICTT23 used rotated reference frames to solve 3D infinite medium problems

  12. Summary • 50+ papers eventually were published on analytical methods for solving inverse transport problems • With a book appendix and a couple of papers Case initiated the exploration of inverse problems in transport theory

More Related