An Efficient Alternating Direction Explicit Method for Solving a Nonlinear Partial Differential Equation

In this paper, the Saul’yev finite difference scheme for a fully nonlinear partial differential equation with initial and boundary conditions is analyzed. The main advantage of this scheme is that it is unconditionally stable and explicit. Consistency and monotonicity of the scheme are discussed. Several finite difference schemes are used to compare the Saul’yev scheme with them. Numerical illustrations are given to demonstrate the efficiency and robustness of the scheme. In each case, it is found that the elapsed time for the Saul’yev scheme is shortest, and the solution by the Saul’yev scheme is nearest to the Crank–Nicolson method.

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Alternating direction implicit finite difference schemes for the Heston-Hull-White partial differential equation

The Journal of Computational Finance ◽

10.21314/jcf.2012.244 ◽

2012 ◽

Vol 16 (1) ◽

pp. 83-110 ◽

Cited By ~ 58

Author(s):

Tinne Haentjens ◽

Karel In 't Hout

Keyword(s):

Differential Equation ◽

Partial Differential Equation ◽

Finite Difference ◽

Difference Schemes ◽

Finite Difference Schemes ◽

Partial Differential ◽

Alternating Direction Implicit ◽

Alternating Direction ◽

Implicit Finite Difference

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Efficient and stable numerical solution of the Heston–Cox–Ingersoll–Ross partial differential equation by alternating direction implicit finite difference schemes

International Journal of Computer Mathematics ◽

10.1080/00207160.2013.777710 ◽

2013 ◽

Vol 90 (11) ◽

pp. 2409-2430 ◽

Cited By ~ 14

Author(s):

Tinne Haentjens

Keyword(s):

Differential Equation ◽

Partial Differential Equation ◽

Finite Difference ◽

Numerical Solution ◽

Difference Schemes ◽

Finite Difference Schemes ◽

Partial Differential ◽

Alternating Direction Implicit ◽

Alternating Direction ◽

Implicit Finite Difference

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Explorations and Expectations of Equidistribution Adaptations for Nonlinear Quenching Problems

Advances in Applied Mathematics and Mechanics ◽

10.4208/aamm.13-13s01 ◽

2013 ◽

Vol 5 (04) ◽

pp. 407-422 ◽

Cited By ~ 2

Author(s):

Matthew A. Beauregard ◽

Qin Sheng

Keyword(s):

Differential Equation ◽

Partial Differential Equation ◽

Finite Difference ◽

Nonlinear Partial Differential Equation ◽

Partial Differential ◽

Spatial Adaptation ◽

Monitor Function ◽

Monitoring Strategies ◽

Highly Nonlinear ◽

Equidistribution Principle

AbstractFinite difference computations that involve spatial adaptation commonly employ an equidistribution principle. In these cases, a new mesh is constructed such that a given monitor function is equidistributed in some sense. Typical choices of the monitor function involve the solution or one of its many derivatives. This straightforward concept has proven to be extremely effective and practical. However, selections of core monitoring functions are often challenging and crucial to the computational success. This paper concerns six different designs of the monitoring function that targets a highly nonlinear partial differential equation that exhibits both quenching-type and degeneracy singularities. While the first four monitoring strategies are within the so-calledprimitiveregime, the rest belong to a later category of themodifiedtype, which requires the priori knowledge of certain important quenching solution characteristics. Simulated examples are given to illustrate our study and conclusions.

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