Comparing iterative methods for linear systems

Question

For a tridiagonal matrix of the from

\begin{bmatrix} a & -b & \newline -b & a & -b \newline & \ddots & \ddots & \ddots \newline & & & & -b \newline & & &-b & a \end{bmatrix}

with $a \geq 2b > 0$ I would like to compare, in funtion of $a$ and $b$, the convergence of the Gauss-Seidel method and the Steepest Descent method. But how to do such a comparison if the information about Gauss-Seidel convergence is given by is spectral radius and the information about the Steepest Descent convergence is given by the ratio between the largest and the smallest eigenvalues?

Answer 1

This is a good question, and I happen to have thought about it. Several comments pointed out that for tridiagonal Toeplitz matrix there are other better algorithms; that's true, but it does not answer the question.

I think the confusion comes from the statement "Gauss-Seidel convergence is given by its spectral radius", which is incorrect. Gauss-Seidel convergence depends on the spectral radius of a new matrix $L^{-1}R$ where $L-R = A$, for solving $Ax=b$. It is hard to estimate the spectral radius of $L^{-1}R$, but I am pretty sure that it is related to the condition number of $A$ (the ratio between the largest and the smallest eigenvalues).