tailieunhanh - Finite difference scheme for initial boundary value problems in financial mathematics

This study develops unconditionally monotone finite-difference scheme of second-order of local approximation on uniform grids for the initial boundary problem value for the Gamma equation through the establishment of two-side estimates for the scheme’s solution. | VNU Journal of Science Mathematics Physics Vol. 35 No. 4 2019 79-86 Original Article Finite-Difference Scheme for Initial Boundary Value Problems in Financial Mathematics Le Minh Hieu1 Truong Thi Hieu Hanh1 Dang Ngoc Hoang Thanh2 1 University of Economics The University of Danang 71 Ngu Hanh Son Da Nang Vietnam 2 Hue College of Industry 70 Nguyen Hue Hue Vietnam Received 02 August 2019 Accepted 11 September 2019 Abstract This study develops unconditionally monotone finite-difference scheme of second-order of local approximation on uniform grids for the initial boundary problem value for the Gamma equation through the establishment of two-side estimates for the scheme s solution. The study considers the initial boundary value problem for the so called Gamma equation which can be derived by transforming the nonlinear Black-Scholes equation for option price into a quasilinear parabolic equation for the second derivative of the option price. By means of regularization principle the previous study results were generalized for construction of unconditionally monotone finite-difference scheme the maximum principle was satisfied without constraints on relations between the coefficients and grid parameters of second order of approximation on uniform grids for this equation. With the help of difference maximum principle the two-side estimates for difference solution were obtained at the arbitrary non-sign-constant input data of the problem. A priori estimate in the maximum norm C was proved. Interestingly the proven two-side estimates for difference solution were fully consistent with differential problem and the maximal and minimal values of the difference solution did not depend on the diffusion and convection coefficients. Finally relevant computational experiments were given to confirm the above-named theoretical findings. Keywords Gamma equation maximum principle two-side estimates monotone finite-difference scheme quasi-linear parabolic equation scientific computing.

• Trung học phổ thông
• Gamma equation
• Maximum principle
• Two side estimates
• Monotone finite difference scheme
• Quasi linear parabolic equation
• Scientific computing
• Non uniform grid
• Stochastic linear dynamical system driven
• Driven by a volterra process
• Volterra driven langevin equation
• Real deterministic function
• Gamma volterra proess
• minimax method
• Microprocessor Programming
• Chemistry
• Biology
• Numerical recipes in Fortran 77
• Fortran 77
• The art of scientific computing
• Fortran Numerical recipes
• Solution of linear algebraic equations
• Integration of functions
• Fast fourier transform
• Statistical description of data
• Integrated Research
• GRID Computing
• scientific technological
• Peer to Peer technologies
• Data Management
• Programming Models
• System Architecture
• Resource Management
• TWO THEORIES FOR COMPUTING
• THE LOGICAL FORM OF MASS EXPRESSIONS
• Francis Jeffry
• scientific reports
• model language
• process natural language
• Computing Term Translation Probabilities
• Generalized Latent Semantic Analysis
• Irina Matveeva
• An Online System
• Corpus Management and Analysis
• Support of Computing in the Humanities
• Centering in the Large
• Computing Referential
• Discourse Segments
• Computing Lattice BLEU Oracle Scores
• Machine Translation
• Artem Sokolov
• Computing Consensus Translation
• Multiple Machine Translation Systems
• Enhanced Hypotheses Alignment
• eastern Sea
• cubic spline functions
• earth sciences
• Research
• scientific research
• Parallel Computing
• Piecewise Hybrid
• Dynamical Systems
• Blockset Software
• Heat Exchangers
• Filter Implementation
• CPU Computing
• Data Archiving
• File Format
• Processing Algorithms
• MATLAB Using
• Large HDF5
• Large HDF