Methods for solving linear, ordinary, and partial differential equations of mathematical physics. Green's functions, distribution theory, integral equations, transforms, potential theory, diffusion ...

This is the first part of a two course graduate sequence in analytical methods to solve ordinary and partial differential equations of mathematical physics. Review of Advanced ODE’s including power ...

Partial differential equations (PDEs) lie at the heart of many different fields of Mathematics and ... singularity formation and pattern formation are analyzed. From the applied side we are interested ...

Introduces ordinary differential equations, systems of linear equations, matrices, determinants, vector spaces, linear transformations, and systems of linear differential equations. Prereq., APPM 1360 ...

Marsha Berger, a trailblazer in the fields of adaptive mesh refinement and embedded boundary methods for partial differential ...

Studies properties and solutions of partial differential equations. Covers methods of characteristics, well-posedness, wave, heat and Laplace equations, Green's functions, and related integral ...

Marsha Berger will deliver this flagship lecture at the Third Joint SIAM/CAIMS Annual Meetings (AN25), happening July ...

The required lower division core courses for a mathematics major are Calculus I, II, and III (MATH 2200, 2205, 2210), Applied Differential Equations I (MATH 2310), Elementary Linear Algebra (MATH 2250 ...

My research interests are in applied and computational mathematics. I am interested in developing and analyzing high-order numerical methods for solving partial differential equations and fractional ...

This analog computer on a chip is useful for certain kinds of operations that CPUs are historically not efficient at, including solving differential equations. Other applications include matrix ...