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/homepage/sac/cam/na2000/index.html7-Volume Set now available at
special set price !
This volume contains contributions in the area of differential
equations and integral equations. Many numerical methods have
arisen in response to the need to solve "real-life" problems in
applied mathematics, in particular problems that do not have a
closed-form solution. Contributions on both initial-value problems
and boundary-value problems in ordinary differential equations
appear in this volume. Numerical methods for initial-value problems
in ordinary differential equations fall naturally into two classes:
those which use one starting value at each step (one-step methods)
and those which are based on several values of the solution
(multistep methods).
John Butcher has supplied an expert's perspective of the
development of numerical methods for ordinary differential
equations in the 20th century.
Rob Corless and Lawrence Shampine talk about established
technology, namely software for initial-value problems using
Runge-Kutta and Rosenbrock methods, with interpolants to fill in
the solution between mesh-points, but the 'slant' is new - based on
the question, "How should such software integrate into the current
generation of Problem Solving Environments?"
Natalia Borovykh and Marc Spijker study the problem of establishing
upper bounds for the norm of the nth power of square
matrices.
The dynamical system viewpoint has been of great benefit to ODE
theory and numerical methods. Related is the study of chaotic
behaviour.
Willy Govaerts discusses the numerical methods for the computation
and continuation of equilibria and bifurcation points of equilibria
of dynamicalsystems.
Arieh Iserles and Antonella Zanna survey the construction of
Runge-Kutta methods which preserve algebraic invariant
functions.
Valeria Antohe and Ian Gladwell present numerical experiments on
solving a Hamiltonian system of Henon and Heiles with a symplectic
and a nonsymplectic method with a variety of precisions and initial
conditions.
Stiff differential equations first became recognized as special
during the 1950s. In 1963 two seminal publications laid to the
foundations for later development: Dahlquist's paper on A-stable
multistep methods and Butcher's first paper on implicit Runge-Kutta
methods.
Ernst Hairer and Gerhard Wanner deliver a survey which retraces the
discovery of the order stars as well as the principal achievements
obtained by that theory.
Guido Vanden Berghe, Hans De Meyer, Marnix Van Daele and Tanja Van
Hecke construct exponentially fitted Runge-Kutta methods with s
stages.
Differential-algebraic equations arise in control, in modelling of
mechanical systems and in many other fields.
Jeff Cash describes a fairly recent class of formulae for the
numerical solution of initial-value problems for stiff and
differential-algebraic systems.
Shengtai Li and Linda Petzold describe methods and software for
sensitivity analysis of solutions of DAE initial-value
problems.
Again in the area of differential-algebraic systems, Neil Biehn,
John Betts, Stephen Campbell and William Huffman present current
work on mesh adaptation for DAE two-point boundary-value
problems.
Contrasting approaches to the question of how good an approximation
is as a solution of a given equation involve (i) attempting to
estimate the actual error (i.e., thedifference between the true and
the approximate solutions) and (ii) attempting to estimate the
defect - the amount by which the approximation fails to satisfy the
given equation and any side-conditions.
The paper by Wayne Enright on defect control relates to carefully
analyzed techniques that have been proposed both for ordinary
differential equations and for delay differential equations in
which an attempt is made to control an estimate of the size of the
defect.
Many phenomena incorporate noise, and the numerical solution of
stochastic differential equations has developed as a relatively new
item of study in the area.
Keven Burrage, Pamela Burrage and Taketomo Mitsui review the way
numerical methods for solving stochastic differential equations
(SDE's) are constructed.
One of the more recent areas to attract scrutiny has been the area
of differential equations with after-effect (retarded, delay, or
neutral delay differential equations) and in this volume we include
a number of papers on evolutionary problems in this area.
The paper of Genna Bocharov and Fathalla Rihan conveys the
importance in mathematical biology of models using retarded
differential equations.
The contribution by Christopher Baker is intended to convey much of
the background necessary for the application of numerical methods
and includes some original results on stability and on the solution
of approximating equations.
Alfredo Bellen, Nicola Guglielmi and Marino Zennaro contribute to
the analysis of stability of numerical solutions of nonlinear
neutral differential equations.
Koen Engelborghs, Tatyana Luzyanina, Dirk Roose, Neville Ford and
Volker Wulf consider the numerics ofbifurcation in delay
differential equations.
Evelyn Buckwar contributes a paper indicating the construction and
analysis of a numerical strategy for stochastic delay differential
equations (SDDEs).
This volume contains contributions on both Volterra and
Fredholm-type integral equations.
Christopher Baker responded to a late challenge to craft a review
of the theory of the basic numerics of Volterra integral and
integro-differential equations.
Simon Shaw and John Whiteman discuss Galerkin methods for a type of
Volterra integral equation that arises in modelling
viscoelasticity.
A subclass of boundary-value problems for ordinary differential
equation comprises eigenvalue problems such as Sturm-Liouville
problems (SLP) and Schrodinger equations.
Liviu Ixaru describes the advances made over the last three decades
in the field of piecewise perturbation methods for the numerical
solution of Sturm-Liouville problems in general and systems of
Schrodinger equations in particular.
Alan Andrew surveys the asymptotic correction method for regular
Sturm-Liouville problems.
Leon Greenberg and Marco Marletta survey methods for higher-order
Sturm-Liouville problems.
R. Moore in the 1960s first showed the feasibility of validated
solutions of differential equations, that is, of computing
guaranteed enclosures of solutions.
Boundary integral equations. Numerical solution of integral
equations associated with boundary-value problems has experienced
continuing interest.
Peter Junghanns and Bernd Silbermann present a selection of modern
results concerning the numerical analysis of one-dimensional Cauchy
singular integral equations, in particular the stability of
operator sequences associated with different projection
methods.
Johannes Elschner and Ivan Graham summarize the most important
results achieved in the last years about the numerical solution of
one-dimensional integral equations of Mellin type of means of
projection methods and, in particular, by collocation
methods.
A survey of results on quadrature methods for solving boundary
integral equations is presented by Andreas Rathsfeld.
Wolfgang Hackbusch and Boris Khoromski present a novel approach for
a very efficient treatment of integral operators.
Ernst Stephan examines multilevel methods for the h-, p- and hp-
versions of the boundary element method, including pre-conditioning
techniques.
George Hsiao, Olaf Steinbach and Wolfgang Wendland analyze various
boundary element methods employed in local discretization
schemes.
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