Strong approximations of stochastic differential equations with jumps

“…Despite their wide interest, however, few analytical solutions have been proposed so far, thus, it is necessary to develop numerical methods and study the properties of these methods. Higham and Kloeden [8,9] studied the convergence of numerical solutions to SDEs with jumps and the stability of implicit method for jump-diffusion systems, Bruti-Liberati and Platen [2,4] developed strong and weak approximations of SDEs with jumps, Chalmers and Higham [7] considered the convergence and stability for the implicit simulation of SDEs with random jump magnitudes. There are extensive literatures on the numerical simulation of stochastic differential delay equations (SDDEs) [5,6,[10][11][12]15,16], and efforts are now being made to bring SDDEs with jumps up to a similar level.…”

Mean-square stability of the Euler–Maruyama method for stochastic differential delay equations with jumps

“…Despite their wide interest, however, few analytical solutions have been proposed so far, thus, it is necessary to develop numerical methods and study the properties of these methods. Higham and Kloeden [8,9] studied the convergence of numerical solutions to SDEs with jumps and the stability of implicit method for jump-diffusion systems, Bruti-Liberati and Platen [2,4] developed strong and weak approximations of SDEs with jumps, Chalmers and Higham [7] considered the convergence and stability for the implicit simulation of SDEs with random jump magnitudes. There are extensive literatures on the numerical simulation of stochastic differential delay equations (SDDEs) [5,6,[10][11][12]15,16], and efforts are now being made to bring SDDEs with jumps up to a similar level.…”

Mean-square stability of the Euler–Maruyama method for stochastic differential delay equations with jumps

“…x → q x is continuous for all (6) Furthermore X t is conservative by theorem 5.2. in [19] using (A1)-(A3). Now the proof will be divided into three parts.…”

The Euler Scheme for Feller Processes

“…Therefore, it is natural to use stochastic differential equations with jumps for modeling these characteristics. The rate of the strong convergence of numerical schemes for stochastic differential equations of this type with Lipschitz coefficients was studied in [6]. However, of special interest is the combination of non-Lipschitz diffusion, which is inherent in most stochastic financial models, and jumps, which are modeled, e.g., by using the Poisson measure.…”

Rate of convergence in the Euler scheme for stochastic differential equations with non-Lipschitz diffusion and Poisson measure