In this paper we introduce a new class of explicit one-step methods of order 2 that can be used for solving stiff problems. This class constitutes a generalization of the two-stage explicit Runge- Kutta methods, with the property of having an A-stability region that varies during the integration in accordance with the accuracy requirements. Some numerical experiments on classical stiff problems are presented
A family of Time-Accurate and Stable Explicit (TASE) methods for the numerical integration of Initia...
A family of Time-Accurate and Stable Explicit (TASE) methods for the numerical integration of Initia...
AbstractThis paper deals with the stability analysis of one-step methods for the numerical solution ...
In this paper we introduce a new class of explicit one-step methods of order 2 that can be used for ...
An algorithm is developed to determine coefficients of the stability polynomials such that the expli...
Stiff problems in ordinary differential equations can now be solved more routinely. In the past four...
An algorithm is developed to determine coefficients of the stability polynomials such that the expli...
In this paper we introduce an explicit one-step method that can be used for solving stiff problems. ...
In this paper we introduce an explicit one-step method that can be used for solving stiff problems. ...
In this paper we introduce an explicit one-step method that can be used for solving stiff problems. ...
A number of techniques and solvers have been suggested, developed, and described, but a clear defini...
AbstractThis paper presents a sixth-order, explicit, one-step method which is proved to be A-stable....
In this article, we extended the existing explicit Taylor method and modified it to gain a new expli...
AbstractFor each integer s≥3, a new uniparametric family of stiffly accurate, strongly A-stable, s-s...
A family of Time-Accurate and Stable Explicit (TASE) methods for the numerical integration of Initia...
A family of Time-Accurate and Stable Explicit (TASE) methods for the numerical integration of Initia...
A family of Time-Accurate and Stable Explicit (TASE) methods for the numerical integration of Initia...
AbstractThis paper deals with the stability analysis of one-step methods for the numerical solution ...
In this paper we introduce a new class of explicit one-step methods of order 2 that can be used for ...
An algorithm is developed to determine coefficients of the stability polynomials such that the expli...
Stiff problems in ordinary differential equations can now be solved more routinely. In the past four...
An algorithm is developed to determine coefficients of the stability polynomials such that the expli...
In this paper we introduce an explicit one-step method that can be used for solving stiff problems. ...
In this paper we introduce an explicit one-step method that can be used for solving stiff problems. ...
In this paper we introduce an explicit one-step method that can be used for solving stiff problems. ...
A number of techniques and solvers have been suggested, developed, and described, but a clear defini...
AbstractThis paper presents a sixth-order, explicit, one-step method which is proved to be A-stable....
In this article, we extended the existing explicit Taylor method and modified it to gain a new expli...
AbstractFor each integer s≥3, a new uniparametric family of stiffly accurate, strongly A-stable, s-s...
A family of Time-Accurate and Stable Explicit (TASE) methods for the numerical integration of Initia...
A family of Time-Accurate and Stable Explicit (TASE) methods for the numerical integration of Initia...
A family of Time-Accurate and Stable Explicit (TASE) methods for the numerical integration of Initia...
AbstractThis paper deals with the stability analysis of one-step methods for the numerical solution ...
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