Systems of ordinary differential equations in which the magnitudes of the eigenvalues (or time constants) vary greatly are commonly called stiff. Such systems of equations arise in nuclear reactor kinetics, the flow of chemically reacting gas, dynamics, control theory, circuit analysis and other fields. The research reported develops an A-stable numerical integration technique for solving stiff systems of ordinary differential equations. The method, which is called the generalized trapezoidal rule, is a modification of the trapezoidal rule. However, the method is computationally more efficient than the trapezoidal rule when the solution of the almost-discontinuous segments is being calculated
Solving ordinary differential equations (ODEs) with solutions in a quasi steady state has been studi...
AbstractThis paper first discusses the conditions in which a set of differential equations should gi...
Abstract: Some results of numerical experiments are described. They illustrate the possibi...
The notion of stiffness of a system of ordinary differential equations is refined. The main difficul...
AbstractWe examine a single-step implicit-integration algorithm which is obtained by a modification ...
AbstractThis paper discusses several aspects of the solution of fluid-flow problems. A model problem...
Some real-world applications involve situations where different physical phenomena acting on very di...
This paper describes a new A- and L-stable integration method for simulating the time-domain transie...
This paper describes a new A-and L-stable integration method for simulating the time-domain transien...
The solving of stiff systems is still a contemporary sophisticated problem. The basic problem is the...
The subject of this book is the solution of stiff differential equations and of differential-algebra...
AbstractIt is shown that Euler's rule, applied on an automatically (and adaptively) determined seque...
Several techniques to improve the reliability and efficiency of generalized stiff integrators in sol...
Two algorithms for the determination of the necessary limit of local error for the numerical so...
The numerical solution of large stiff systems of ordinary differential equations is very expensive...
Solving ordinary differential equations (ODEs) with solutions in a quasi steady state has been studi...
AbstractThis paper first discusses the conditions in which a set of differential equations should gi...
Abstract: Some results of numerical experiments are described. They illustrate the possibi...
The notion of stiffness of a system of ordinary differential equations is refined. The main difficul...
AbstractWe examine a single-step implicit-integration algorithm which is obtained by a modification ...
AbstractThis paper discusses several aspects of the solution of fluid-flow problems. A model problem...
Some real-world applications involve situations where different physical phenomena acting on very di...
This paper describes a new A- and L-stable integration method for simulating the time-domain transie...
This paper describes a new A-and L-stable integration method for simulating the time-domain transien...
The solving of stiff systems is still a contemporary sophisticated problem. The basic problem is the...
The subject of this book is the solution of stiff differential equations and of differential-algebra...
AbstractIt is shown that Euler's rule, applied on an automatically (and adaptively) determined seque...
Several techniques to improve the reliability and efficiency of generalized stiff integrators in sol...
Two algorithms for the determination of the necessary limit of local error for the numerical so...
The numerical solution of large stiff systems of ordinary differential equations is very expensive...
Solving ordinary differential equations (ODEs) with solutions in a quasi steady state has been studi...
AbstractThis paper first discusses the conditions in which a set of differential equations should gi...
Abstract: Some results of numerical experiments are described. They illustrate the possibi...