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2020-11-17 21:35:52 +01:00
* IRPJAST
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CHAMP's Jastrow factor computation using the IRPF90 method
Original equation:
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$$
\sum_{i=2}^{Ne} \sum_{j=1}^i \sum_{pkl} \sum_a^{Nn} c_{apkl}\, r_{ij}^k\, ( R_{ia}^l + R_{ja}^l) ( R_{ia} R_{ja})^m
$$
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Expanding, one obtains:
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$$
\sum_{i=2}^{Ne} \sum_{j=1}^i \sum_{pkl} \sum_a^{Nn} c_{apkl} R_{ia}^{p-k-l}\, r_{ij}^k\, R_{ja}^{p-k+l} + c_{apkl} R_{ia}^{p-k+l}\, r_{ij}^k\, R_{ja}^{p-k-l}
$$
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The equation is symmetric if we exchange $i$ and $j$, so we can rewrite
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$$
\sum_{i=1}^{Ne} \sum_{j=1}^{Ne} \sum_{pkl} \sum_a^{Nn} c_{apkl} R_{ia}^{p-k-l}\, r_{ij}^k\, R_{ja}^{p-k+l}
$$
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If we reshape $R_{ja}^p$ as a matrix $R_{j,al}$ of size
$N_e \times N_n(N_c+1)$,
for every $k$, we can pre-compute the matrix product
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$$
C_{i,al}^{k} = \sum_j r_{ij}^k\, R_{i,al}
$$
which can be computed efficiently with BLAS.
We can express the total Jastrow as:
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$$
\sum_{i=1}^{Ne} \sum_{pkl} \sum_a^{Nn}
c_{apkl} R_{ia}^{p-k-l}\, C_{i,a(p-k+l)}^k
$$
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* Running
#+begin_src bash :var Ratio=5 Natoms=500
python ./generateData.py -a $Natoms -r $Ratio
#+end_src
Cela genere les trois fichiers:
geometry.txt
elec_coords.txt
jast_coeffs.txt
#+begin_src bash :var Natoms=500
./codelet_factor_een_blas $Natoms
#+end_src