Publication Date
5-5-1969
Abstract
In 1944 von Neumann Conjectures that only averages of numerical solutions, produced by a discrete scheme he had proposed to solve hydrodynamic shock problems, would converge as the meshes were refined. The hydrodynamic shock problem is defined here as: Find a solution, allowing discontinuous solutions, to the three conservation laws, the increasing-entropy law, and the ideal-gas law when giben physically acceptable initial and boundary values. For discrete schemes similar to von Neumann’s, it is verified that the averages do converge and it appears that von Neumann was also correct in surmising that only the averages converge. A smoothing device named “conservative smoothing” is developed and has been successfully introduced into one-, two-, and three=dimension hydrocodes. A conservative, discrete scheme with conservative smoothing, in the one-dimension Lagrangian formulation, produces in the limit, for a suitable chosen sequence of meshes, generalized functions which satisfy the conservation laws. A priori bounds and convergence and compactness lemmas for sequences of solution refinements in Lp-spaces are developed.
Degree Name
Mathematics
Level of Degree
Doctoral
Department Name
Mathematics & Statistics
First Committee Member (Chair)
Bernard Epstein
Second Committee Member
Reuben Hersh
Third Committee Member
Donald Ward Dubois
Fourth Committee Member
Richard Clyde Metzler
Language
English
Document Type
Dissertation
Recommended Citation
Hicks, Darrell Lee. "The Convergence Of Numerical Solutions Of Hydrodynamic Shock Problems.." (1969). https://digitalrepository.unm.edu/math_etds/259