Iterative methods
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===Stationary Iterative Methods=== | ===Stationary Iterative Methods=== | ||
| - | Iterative methods that can be expressed in the simple form | + | Iterative methods that can be expressed in the simple form |
| + | |||
:<math> | :<math> | ||
x^{(k+1)} = Bx^{(k)} + c | x^{(k+1)} = Bx^{(k)} + c | ||
| - | </math> | + | </math> |
| + | |||
| + | when neither '''B''' nor '''c''' depend upon the iteration count (k), the iterative method is called stationary iterative method. Some of the stationary iterative methods are | ||
| - | |||
#Jacobi method | #Jacobi method | ||
#Gauss-Seidel method | #Gauss-Seidel method | ||
#Successive Overrelaxation (SOR) method and | #Successive Overrelaxation (SOR) method and | ||
#Symmetric Successive Overrelaxation (SSOR) method | #Symmetric Successive Overrelaxation (SSOR) method | ||
| + | |||
| + | The convergence of such iterative methods can be investigated using the [[Fixed point theorem]]. | ||
===Nonstationary Iterative Methods=== | ===Nonstationary Iterative Methods=== | ||
Revision as of 11:00, 19 October 2005
For solving a set of linear equations, we seek the solution to the problem:
After k iterations we obtain an approaximation to the solution as:
where 
is the residual after k iterations.
Defining:
as the difference between the exact and approaximate solution.
we obtain :
the purpose of iterations is to drive this residual to zero.
Stationary Iterative Methods
Iterative methods that can be expressed in the simple form
when neither B nor c depend upon the iteration count (k), the iterative method is called stationary iterative method. Some of the stationary iterative methods are
- Jacobi method
- Gauss-Seidel method
- Successive Overrelaxation (SOR) method and
- Symmetric Successive Overrelaxation (SSOR) method
The convergence of such iterative methods can be investigated using the Fixed point theorem.
Nonstationary Iterative Methods
When during the iterations B and c changes during the iterations, the method is called Nonstationary Iterative Method. Typically, constants B and c are computed by taking inner products of residuals or other vectors arising from the iterative method.
Some examples are:
- Conjugate Gradient Method (CG)
- MINRES and SYMMLQ
- Generalized Minimal Residual (GMRES)
- BiConjugate Gradient (BiCG)
- Quasi-Minimal Residual (QMR)
- Conjugate Gradient Squared Method (CGS)
- BiConjugate Gradient Stabilized (Bi-CGSTAB)
- Chebyshev Iteration
Return to Numerical Methods
