This site is being phased out.

Discrete differential geometry

From Mathematics Is A Science
Jump to navigationJump to search

Partial differential equations are equations with respect to derivatives of some unknown functions. To solve them numerically one might "sample" or "discretize" these derivatives via finite differences. Instead, we look at the derivations of of some typical PDEs (heat, wave, fluid flow etc) and, based on the physics, represent all the quantities involved as differential forms or, better, discrete differential forms whenever possible. These quantities have to satisfy the basic laws of physics (conservation of energy, mass, etc) that take a form of differential and algebraic equations. The discrete versions of these equations provide ready-made simulations (i.e., numerical solutions) of these PDEs. They are similar to cellular automata. The advantage of this approach is that the laws of physics, by design, are satisfied exactly rather than approximately, as is the case with discretization of PDEs. The next main issue is that, even if the discrete PDE is physically valid, it may not approximate its continuous counterpart. This fact is frequently revealed by the former's anisotropic behavior. We follow a broad approach to these issues by developing, in addition to differential calculus, its discrete version as well as other possible calculi. We borrow the necessary tools from algebraic topology.


Algebraic topology

Discrete exterior calculus

Simulations of PDEs based on the physics

Tools of discrete exterior calculus: