| 2. | GetDP (a General environment for the treatment of Discrete Problems) | | | A scientific software environment for the numerical solution of integro-differential equations, open to the coupling of physical problems (electromagnetic, acoustic, thermal, mechanical, ...) as well as of numerical methods (finite element methods, boundary element and integral methods, ...).
www.geuz.org |
| 3. | MGNet | | | Information related to multigrid, multilevel, multiscale, aggregation, defect correction, and domain decomposition methods.
www.mgnet.org |
| 4. | Nonlinear Differential Equations at Glasgow | | | The site describes research activities of the differential equations group in the mathematics department at the university of Glasgow, UK, and provides some resources of a general nature.
www.maths.gla.ac.uk |
| 8. | Computational PDEs Unit | | | School of Computing, University of Leeds. Research details, publications, software and resources.
www.scs.leeds.ac.uk |
| 10. | Stripf's Homepage | | | A Java Applet to illustrate and solve initial value problems. Uses different numerical methods (e.g. Runge-Kutta) that can be compared to each other.
www.stripf.com |
| 12. | PRIDE | | | Products by Rapid Integrated Detailed Engineering. An application of PDEs in engineering design.
www.amsta.leeds.ac.uk |
| 13. | Analytic Solution for the Burgers Equation | | | Provides the general analytic solution for the Burgers equation in the form of a 4-D commutative hypercomplex function. The solution exhibits the main dynamic features in a Burgers medium: propagation of disturbances, shock waves, propagating state change fronts, and solitons. A page is included to explain the hypercomplex mathematics.
home.usit.net |
| 14. | Table of Laplace Transforms | | | This page contains an extensive table of Laplace transforms. Laplace transforms are used to solve certain differential equations.
www.vibrationdata.com |
| 15. | Difference Method for Numerical Approximation to Applied Differential Equations. | | | This page explains how to use the difference formula of differentials to approximate the differential equations for applied systems. This method is used when analytical techniques are unavailable or cause computers to spit out garbage. This difference method is very similar to the Runge-Kata and Newton's method.
www.geocities.com |
| 18. | Finding Green's Functions for ODEs | | | A brief but technical overview of methods of finding Green's functions. By Evans M. Harrell II and James V. Herod.
www.mathphysics.com |
| 19. | Introduction to Green's Functions | | | Green's functions play an important role in the solution of linear ordinary and partial differential equations, and are a key component to the development of boundary integral equation methods.
www.boulder.nist.gov |
| 20. | Green's Function Theory | | | A set of lecture notes on Green's functions and their applications.
www.math.ohio-state.edu |
| 21. | Linear Mathematics in Infinite Dimensions | | | A set of lecture notes on the mathematical framework that underlies linear systems arising in physics, engineering and applied mathematics.
www.math.ohio-state.edu |
| 23. | PDEase2D 3.0 | | | Solves partial differential equations numerically by finite element analysis for use in such problems as heat transfer, reaction diffusion, solid and fluid mechanics, electromagnetics, groundwater flow, and quantum mechanics.
www.scientek.com |
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