Assessment of continuous and discrete adjoint method for sensitivity analysis in two-phase flow simulations (1805.08083v1)

Abstract: The efficient method for computing the sensitivities is the adjoint method. The cost of solving an adjoint equation is comparable to the cost of solving the governing equation. Once the adjoint solution is obtained, the sensitivities to any number of parameters can be obtained with little effort. There are two methods to develop the adjoint equations: continuous method and discrete method. In the continuous method, the control theory is applied to the forward governing equation and produces an analytical partial differential equation for solving the adjoint variable; in the discrete method, the control theory is applied to the discrete form of the forward governing equation and produces a linear system of equations for solving the adjoint variable. In this article, an adjoint sensitivity analysis framework is developed using both the continuous and discrete methods. These two methods are assessed with the faucet flow for steady-state problem and one transient test case based on the BFBT benchmark for transient problem. Adjoint sensitivities from both methods are verified by sensitivities given by the perturbation method. Adjoint sensitivities from both methods are physically reasonable and match each. The sensitivities obtained with discrete method is found to be more accurate than the sensitivities from the continuous method. The continuous method is computationally more efficient than the discrete method because of the analytical coefficient matrices and vectors. However, difficulties are observed in solving the continuous adjoint equation for cases where the adjoint equation contains sharp discontinuities in the source terms; in such cases, the continuous method is not as robust as the discrete adjoint method.