Parallel Two-level Stabilized Finite Element Algorithms for Unsteady Navier-Stokes Equations

doi:10.19596/j.cnki.1001-246x.8546

Abstract

Abstract:

In numerical solution of unsteady Navier-Stokes equations with standard finite element method, errors of computed velocity are usually affected by pressure errors, where smaller viscosity coefficients lead to greater velocity errors. To improve pressurerobustness, in this paper, we introduce a grad-div stabilization term to improve accuracy of approximate solutions. We present parallel two-level grad-div stabilized finite element algorithms for unsteady Navier-Stokes equations, where implicit Euler scheme and Galerkin finite element methods are used for temporal and spatial discretizations, respectively. At each time step, firstly we solve a nonlinear Navier-Stokes problem with grad-div stabilization on a coarse grid, and then linearized and grad-div stabilized problems are solved with Stokes, Oseen and Newton iterations on overlapping fine grid subdomains in a parallel manner to correct the coarse grid solution. Finally, numerical experiments are given to verify correctness of theoretical predictions and demonstrate effectiveness of the algorithms.

Key words: unsteady Navier-Stokes equations, grad-div stabilization, two-level method, parallel algorithm, finite element method

Zhanhuang WANG, Bo ZHENG, Yueqiang SHANG. Parallel Two-level Stabilized Finite Element Algorithms for Unsteady Navier-Stokes Equations[J]. Chinese Journal of Computational Physics, 2023, 40(1): 14-28.

Figures/Tables 11

References 32

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算法	h	H	CPU/s	E_u	E_p	收敛阶
算法3.1	1/27	1/18	7.782	2.283 × 10^-3	2.947 × 10^-3
	1/64	1/32	23.472	4.923 × 10^-4	4.444 × 10^-4	2.044
	1/125	1/50	62.289	1.186 × 10^-4	1.595 × 10^-4	2.060
算法3.2	1/27	1/18	7.553	2.832 × 10^-3	2.943 × 10^-3
	1/64	1/32	23.519	4.923 × 10^-4	4.444 × 10^-4	2.043
	1/125	1/50	63.909	1.186 × 10^-4	1.595 × 10^-4	2.060
算法3.3	1/27	1/18	6.86	2.833 × 10^-3	2.931 × 10^-3
	1/64	1/32	23.222	4.934 × 10^-4	4.456 × 10^-4	2.041
	1/125	1/50	63.645	1.191 × 10^-4	1.586 × 10^-4	2.059

算法	h	H	CPU/s	E_u	E_p	收敛阶
算法3.1	1/27	1/18	7.782	2.283 × 10^-3	2.947 × 10^-3
	1/64	1/32	23.472	4.923 × 10^-4	4.444 × 10^-4	2.044
	1/125	1/50	62.289	1.186 × 10^-4	1.595 × 10^-4	2.060
算法3.2	1/27	1/18	7.553	2.832 × 10^-3	2.943 × 10^-3
	1/64	1/32	23.519	4.923 × 10^-4	4.444 × 10^-4	2.043
	1/125	1/50	63.909	1.186 × 10^-4	1.595 × 10^-4	2.060
算法3.3	1/27	1/18	6.86	2.833 × 10^-3	2.931 × 10^-3
	1/64	1/32	23.222	4.934 × 10^-4	4.456 × 10^-4	2.041
	1/125	1/50	63.645	1.191 × 10^-4	1.586 × 10^-4	2.059

ν	算法3.1		无稳定项的并行算法
ν	E_u	E_p	E_u	E_p
1	1.126 3 × 10^-4	6.216 51 × 10^-4	1.119 99 × 10^-4	5.582 96 × 10^-4
10^-1	1.175 85 × 10^-4	2.083 03 × 10^-4	1.126 32 × 10^-4	2.036 05 × 10^-4
10^-2	1.311 98 × 10^-4	1.933 03 × 10^-4	1.420 51 × 10^-4	2.002 67 × 10^-4
10^-3	3.479 11 × 10^-4	1.946 46 × 10^-4	6.041 92 × 10^-4	1.984 52 × 10^-4
10^-4	5.473 91 × 10^-4	1.966 75 × 10^-4	1.536 08 × 10^-3	1.994 52 × 10^-4
10^-5	5.915 42 × 10^-4	1.970 91 × 10^-4	1.937 1 × 10^-3	1.999 92 × 10^-4
10^-6	5.968 42 × 10^-4	1.971 32 × 10^-4	1.989 61 × 10^-3	2.000 63 × 10^-4

ν	算法3.1		无稳定项的并行算法
ν	E_u	E_p	E_u	E_p
1	1.126 3 × 10^-4	6.216 51 × 10^-4	1.119 99 × 10^-4	5.582 96 × 10^-4
10^-1	1.175 85 × 10^-4	2.083 03 × 10^-4	1.126 32 × 10^-4	2.036 05 × 10^-4
10^-2	1.311 98 × 10^-4	1.933 03 × 10^-4	1.420 51 × 10^-4	2.002 67 × 10^-4
10^-3	3.479 11 × 10^-4	1.946 46 × 10^-4	6.041 92 × 10^-4	1.984 52 × 10^-4
10^-4	5.473 91 × 10^-4	1.966 75 × 10^-4	1.536 08 × 10^-3	1.994 52 × 10^-4
10^-5	5.915 42 × 10^-4	1.970 91 × 10^-4	1.937 1 × 10^-3	1.999 92 × 10^-4
10^-6	5.968 42 × 10^-4	1.971 32 × 10^-4	1.989 61 × 10^-3	2.000 63 × 10^-4

子区域数	E_u	E_p
2 × 2	2.283 21 × 10^-3	2.947 28 × 10^-3
2 × 4	2.554 87 × 10^-3	2.092 27 × 10^-3
4 × 4	2.566 64 × 10^-3	2.133 74 × 10^-3