Finite element theta schemes for the viscous Burgers' equation with nonlinear Neumann boundary feedback control

In this article, we develop a fully discrete numerical scheme for the one-dimensional (1D) and two-dimensional (2D) viscous Burgers equations with nonlinear Neumann boundary feedback control. The temporal discretization employs a $θ$-scheme, while a conforming finite element method is used for the spatial approximation. The existence and uniqueness of the fully discrete solution are established. We further prove that the scheme is unconditionally exponentially stable for $θ\in [1/2, 1]$, thereby ensuring that the stabilization property of the continuous model is retained at the discrete level. In addition, optimal error estimates are obtained for both the state variable and the boundary control inputs in 1D and 2D frameworks. Finally, several numerical experiments are presented to validate our theoretical findings and to demonstrate the effectiveness of the proposed stabilization strategy under varying model parameters.

💡 Research Summary

This paper presents a fully discrete numerical framework for the viscous Burgers equation equipped with nonlinear Neumann boundary feedback control, addressing both one‑dimensional (1D) and two‑dimensional (2D) settings. The authors employ a θ‑scheme for temporal discretization, where the parameter θ∈