Continuously Bounds-Preserving Discontinuous Galerkin Methods for Hyperbolic Conservation Laws

The proposed continuously bounds-preserving DG approach has the potential for various applications and extensions beyond hyperbolic conservation laws. One possible application is in the field of fluid dynamics, particularly in simulating flows with complex geometries where maintaining physical constraints is crucial. This approach could be utilized in modeling turbulent flows, multiphase flows, and even in simulations involving chemical reactions. Additionally, the method could be extended to problems in structural mechanics, such as in the analysis of materials with nonlinear constitutive laws or in the simulation of dynamic structural responses under various loading conditions. Furthermore, the concept of continuously bounds-preserving methods could be applied in the context of optimization problems where constraints need to be satisfied throughout the optimization process. Overall, the approach has the potential to enhance the accuracy and robustness of numerical simulations in a wide range of scientific and engineering applications.

To improve the proposed limiting formulation for better approximating the minimum necessary limiting factor for arbitrary nonlinear constraint functionals, several strategies could be considered. One approach could involve incorporating adaptive strategies within the optimization procedure to dynamically adjust the limiting factor based on the local behavior of the constraint functional. This adaptive approach could involve refining the optimization process in regions where the constraint violation is significant, thereby focusing computational resources on areas where the limiting factor needs to be more accurately determined. Additionally, exploring advanced optimization algorithms that can handle non-convex and nonlinear constraints more effectively, such as genetic algorithms or particle swarm optimization, could help in finding better approximations to the minimum necessary limiting factor. Furthermore, incorporating sensitivity analysis techniques to assess the impact of variations in the constraint functionals on the limiting factor could provide insights into refining the limiting formulation for improved accuracy in enforcing constraints continuously.

The choice between using global non-convex optimization techniques and the local convex optimization approach presented in this work involves several computational trade-offs and performance implications. Global non-convex optimization methods, such as branch-and-bound algorithms, offer the advantage of potentially finding the global minimum of the constraint functional, ensuring that the limited solution is continuously bounds-preserving across the entire element. However, these methods typically require more computational resources and may have higher algorithmic complexity, especially for problems with a large number of constraints or complex nonlinearities. On the other hand, the local convex optimization approach, utilizing Newton–Raphson and gradient descent methods, is computationally more efficient and faster, making it suitable for real-time or iterative simulations. While this approach may not guarantee finding the global minimum, it often provides satisfactory results and is well-suited for practical implementation in numerical simulations. The choice between these approaches would depend on the specific requirements of the problem, balancing computational cost, accuracy, and efficiency in enforcing continuous constraints in DG methods.