We propose a kernel preserving multigrid approach for solving convection-diffusion equations. The multigrid methods use Petrov-Galerkin coarse grid correction and linear interpolation. The restriction operator is constructed by preserving the kernel of the convection-diffusion operator. The construction considers constant and variable coefficient problems as well as cases where the convection term is not known explicitly. For constant convection-diffusion problems, we prove that the resulting Petrov-Galerkin coarse grid correction has small phase errors and the coarse grid matrix is essentially an M-matrix. The algebraic construction of the interpolation and restriction operators is a generalization of the energy minimization approach for elliptic PDEs.
Denote the iteration matrix of multigrid (2-level) as follows:
where P = prolongation and R = restriction. The Fourier symbol of the coarse grid correction matrix C is:
We are interested in small frequencies |μ|, |ν| ≈ 0. If one ignores the effect of P & R, then
Denote the strength of convection by β. As β → ∞, the coarse and fine grid matrices differ by
Thus, the coarse grid matrix shifts waves of all frequencies by 1 grid point to the right. (Similar, it shifts by 1 grid point to the left if β → -∞. Hence, the coarse grid error is off by 1 grid point, resulting in at best first order accuracy.
If one considers the effect of the kernel preserving restriction, then
Thus the kernel preserving restriction counteracts the shifting caused by the coarse grid matrix.
To summarize, the phase errors of various coarse grid matrices:
| Petrov-Galerkin | Direct discretization | Galerkin | |
| Cross-characteristic components (μ = ν) | O(μπh)^2 | O(μπh) | O(μπh)^3 |
| Characteristic components (μ = -ν) | O(μπh)^4 | 1/2 | O(μπh)^2 |
Stability analysis
Consider the Petrov-Galerkin coarse grid matrix AH = R Ah P, R = kernel preserving restriction, P = linear interpolation. Assume Ah is an M-matrix (e.g. Scharfetter-Gummel discretization). Then
Thus, for |β| is sufficiently large, then AH is numerically an M-matrix.
BMG = Blackbox multigrid
EMG(Jac) = our multigrid with Jacobi smoothing
EMG(GS1) = our multigrid with GS smoothing (order first in x (left to right)
and then y (bottom to top))
EMG(GS2) = our multigrid with GS smoothing (order first in y (top to bottom)
and then x (left to right))
EMG(GS3) = our multigrid with GS smoothing (order first in x (right to left)
and then y (top to bottom))
EMG(GS4) = our multigrid with GS smoothing (order first in y (bottom to top)
and then x (right to left))
| δ | BMG | EMG(Jac) | EMG(GS1) | EMG(GS2) | EMG(GS3) | EMG(GS4) |
| 1 | 11 | 11 | 6 | 6 | 8 | 6 |
| 1/2 | 13 | 10 | 5 | 7 | 9 | 7 |
| 1/4 | 20 | 10 | 4 | 6 | 11 | 6 |
| 1/8 | >20 | 9 | 3 | 8 | 15 | 8 |
| 1/16 | >20 | 9 | 3 | 10 | 18 | 10
|
| h | EMG(Jac) | EMG(GS1) | EMG(GS2) | EMG(GS3) | EMG(GS4) |
| 1/16 | 9 | 2 | 6 | 11 | 6 |
| 1/32 | 9 | 2 | 10 | 18 | 10 |
| 1/64 | 9 | 3 | 15 | 28 | 15 |
| 1/128 | 9 | 3 | 12 | 14 | 12
|
Example 2: recirculating flow
a = 4x(x-1)(1-2y), b = -4y(y-1)(1-2x).
| h | EMG(βmidpt) | EMG(βave) | EMG(βweighted) |
| 1/16 | 6 | 6 | 4 |
| 1/32 | 7 | 7 | 6 |
| 1/64 | 10 | 10 | 8 |
| 1/128 | 12 | 12 | 10
|
Example 3: Asian option pricing
S = stock price
A = arithmetic average of the stock price over some time interval
T
τ = time from the expiration date T
r = interest rate
σ = volatility
Note: (1) There is no diffusion in the A direction. (2) The convection approaches infinity as τ approaches the expiration date T.
| σ | T | Analytic | Numerical | EMG(GS) |
| 0.1 | 0.25 | 98.763 | 98.7604 | 12 |
| 0.50 | 97.547 | 97.5411 | 9 | |
| 1.00 | 95.175 | 95.1626 | 6 | |
| 0.2 | 0.25 | 98.763 | 98.7574 | 12 |
| 0.50 | 97.547 | 97.5309 | 9 | |
| 1.00 | 95.175 | 95.1785 | 6 | |
| 0.4 | 0.25 | 98.763 | 98.7673 | 12 |
| 0.50 | 97.547 | 97.5447 | 9 | |
| 1.00 | 95.175 | 95.1633 | 6
|