Truncated EM Scheme for Multiple-Delay SDEs with Irregular Coefficients

Implicit schemes are often used to approximate stochastic differential equations (SDEs) with superlinear coefficients, as explicit schemes may diverge for such cases. While explicit schemes like the Euler-Maruyama method are straightforward and easy to implement, they can struggle with SDEs that have superlinear growth conditions in their coefficients. On the other hand, implicit schemes involve solving equations iteratively or using advanced techniques to handle the nonlinearity of the problem more effectively. Implicit schemes tend to be more stable and accurate for a wider range of SDEs compared to explicit schemes.

Locally Hölder continuous diffusion coefficients play a crucial role in numerical schemes for stochastic differential equations (SDEs). These coefficients indicate how smooth or rough the paths of the process are over small time intervals. When dealing with locally Hölder continuous diffusion coefficients, numerical methods need to account for this irregularity by adjusting their approximation techniques accordingly. The irregularity introduced by these coefficients can impact convergence rates and stability of numerical solutions. Therefore, understanding and incorporating these characteristics into numerical schemes is essential for accurately modeling systems with such properties.

The findings of this study on truncated Euler-Maruyama scheme for multiple-delay stochastic differential equations (SDEs) with irregular coefficients have significant implications in real-world financial modeling beyond just stochastic volatility models. By developing efficient numerical methods that can handle complex SDEs with superlinear terms and multiple delays, researchers and practitioners can better model intricate financial systems where traditional analytical solutions may not be feasible. These advanced numerical techniques can enhance risk management strategies, derivative pricing models, portfolio optimization algorithms, and other financial applications that rely on accurate simulations of uncertain processes governed by SDEs. Additionally, insights from this study could contribute to improving computational efficiency in analyzing market data trends, assessing investment risks under various scenarios, and designing robust trading strategies based on sophisticated mathematical models tailored to specific financial instruments or markets.