Preconditioning

The idea is to find a matrix which multiplied with the residual vector gives the exact error in the wavefunction. Formally this matrix (the Greens function) can be written down and is given by

${\displaystyle {\frac {1}{{\bf {H}}-\epsilon _{n}}},}$

where $ \epsilon_n$ is the exact eigenvalue for the band in interest. Actually the evaluation of this matrix is not possible, recognizing that the kinetic energy dominates the Hamiltonian for large ${\displaystyle G}$-vectors (i.e. ${\displaystyle H_{G,G'}\to \delta _{G,G'}{\frac {\hbar ^{2}}{2m}}G^{2}}$), it is a good idea to approximate the matrix by a diagonal function which converges to ${\displaystyle {\frac {2m}{\hbar ^{2}G^{2}}}}$ for large ${\displaystyle G}$ vectors, and possess a constant value for small ${\displaystyle G}$ vectors. We actually use the preconditioning function proposed by Teter et. al^[1]

Failed to parse (unknown function "\bG"): {\displaystyle \langle \bG | {\bf K} | \bG'\rangle = \delta_{\bG \bG'} \frac{ 27 + 18 x+12 x^2 + 8x^3} {27 + 18x + 12x^2+8x^3 +16x^4} \quad \mbox{und} \quad x = \tp \frac{G^2} {1.5 E^{\rm kin}( \bR) }, }

with Failed to parse (unknown function "\bR"): {\displaystyle E^{\rm kin}(\bR)} being the kinetic energy of the residual vector. The preconditioned residual vector is then simply

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