IMIX: Difference between revisions

Revision as of 17:08, 7 February 2011

IMIX = 0 | 1 | 2 | 3 | 4
Default: IMIX = 4

Description: IMIX specifies the type of mixing.

IMIX=0: no mixing.

\rho _{\rm {mix}}=\rho _{\rm {out}}

IMIX=1: Kerker mixing.^[1]

The mixed density is given by

\rho _{\rm {mix}}\left(G\right)=\rho _{\rm {in}}\left(G\right)+A{\frac {G^{2}}{G^{2}+B^{2}}}{\Bigl (}\rho _{\rm {out}}\left(G\right)-\rho _{\rm {in}}\left(G\right){\Bigr )}

with

A

=AMIX and

B

=BMIX

If BMIX is chosen to be very small, e.g. BMIX=0.0001, a simple straight mixing is obtained. Please mind, that BMIX=0 might cause floating point exceptions on some platforms.

IMIX=2: A variant of the popular Tchebycheff mixing scheme.^[2]

In our implementation a second order equation of motion is used, that reads:

{\ddot {\rho }}_{\rm {in}}\left(G\right)=2*A{\frac {G^{2}}{G^{2}+B^{2}}}{\Bigl (}\rho _{\rm {out}}\left(G\right)-\rho _{\rm {in}}\left(G\right){\Bigr )}-\mu {\dot {\rho }}_{\rm {in}}\left(G\right)

with

A

=AMIX,

B

=BMIX, and

\mu

=AMIN.

A simple velocity Verlet algorithm is used to integrate this equation, and the discretized equation reads (the index N now refers to the electronic iteration, F is the force acting on the charge):

{\dot {\rho }}_{N+1/2}={\Bigl (}\left(1-\mu /2\right){\dot {\rho }}_{N-1/2}+2*F_{N}{\Bigr )}/\left(1+\mu /2\right)

where

F\left(G\right)=A{\frac {G^{2}}{G^{2}+B^{2}}}{\Bigl (}\rho _{\rm {out}}\left(G\right)-\rho _{\rm {in}}\left(G\right){\Bigr )}

and

\rho _{N+1}=\rho _{N+1}+{\dot {\rho }}_{N+1/2}

.

IMIX=3
IMIX=4

Related Tags and Sections

INIMIX, MAXMIX, AMIX, BMIX, AMIX_MAG, BMIX_MAG, AMIN, MIXPRE, WC

References

Contents

[kerker:prb:81-1] G. P. Kerker, Phys. Rev. B 23, 3082 (1981).

[akai:jpc:85-2] H. Akai and P.H. Dederichs, J. Phys. C 18 (1985).

[1]

[2]

@@ Line 7: / Line 7: @@
 *{{TAG|IMIX}}=1: Kerker mixing.<ref name="kerker:prb:81"/>
 :The mixed density is given by
-::<math>\rho_{\rm mix}\left(G\right)=\rho_{\rm in}\left(G\right)+A \frac{G^2}{G^2+B^2}\left(\rho_{\rm out}\left(G\right)-\rho_{\rm in}\left(G\right)\right)</math>
+::<math>\rho_{\rm mix}\left(G\right)=\rho_{\rm in}\left(G\right)+A \frac{G^2}{G^2+B^2}\Bigl(\rho_{\rm out}\left(G\right)-\rho_{\rm in}\left(G\right)\Bigr)</math>
 :with <math>A</math>={{TAG|AMIX}} and <math>B</math>={{TAG|BMIX}}
@@ Line 14: / Line 14: @@
 *{{TAG|IMIX}}=2: A variant of the popular Tchebycheff mixing scheme.<ref name="akai:jpc:85"/>
 :In our implementation a second order equation of motion is used, that reads:
-::<math>\ddot{\rho}_{\rm in}\left(G\right) = 2*A \frac{G^2}{G^2+B^2}\left(\rho_{\rm out}\left(G\right)-\rho_{\rm in}\left(G\right)\right)-\mu \dot{\rho}_{\rm in}\left(G\right)</math>
+::<math>\ddot{\rho}_{\rm in}\left(G\right) = 2*A \frac{G^2}{G^2+B^2}\Bigl(\rho_{\rm out}\left(G\right)-\rho_{\rm in}\left(G\right)\Bigr)-\mu \dot{\rho}_{\rm in}\left(G\right)</math>
 :with <math>A</math>={{TAG|AMIX}}, <math>B</math>={{TAG|BMIX}}, and <math>\mu</math>={{TAG|AMIN}}.
+:A simple velocity Verlet algorithm is used to integrate this equation, and the discretized equation reads (the index ''N'' now refers to the electronic iteration, ''F'' is the force acting on the charge):
+::<math>\dot{\rho}_{N+1/2} =  \Bigl(\left(1-\mu/2\right) \dot{\rho}_{N-1/2} + 2*F_N \Bigr)/\left(1+\mu/2\right)</math>
+:where
+::<math>F\left(G\right)=A\frac{G^2}{G^2+B^2} \Bigl(\rho_{\rm out}\left(G\right)-\rho_{\rm in}\left(G\right)\Bigr)</math>
+:and
+::<math>\rho_{N+1}=\rho_{N+1}+\dot{\rho}_{N+1/2}</math>.
 *{{TAG|IMIX}}=3