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QCaml/mo/lib/basis.ml

205 lines
5.6 KiB
OCaml

open Linear_algebra
(** One-electron orthogonal basis set, corresponding to Molecular Orbitals. *)
module HF = Hartree_fock
module Si = Simulation
type ao = Ao.Ao_dim.t
type mo = Mo_dim.t
type mo_type =
| RHF | ROHF | UHF | CASSCF | Projected
| Natural of string
| Localized of string
type t =
{
simulation : Simulation.t; (* Simulation which produced the MOs *)
mo_type : mo_type; (* Kind of MOs (RHF, CASSCF, Localized...) *)
mo_occupation : mo Vector.t; (* Occupation numbers *)
mo_coef : (ao,mo) Matrix.t; (* Matrix of the MO coefficients in the AO basis *)
eN_ints : (mo,mo) Matrix.t lazy_t; (* Electron-nucleus potential integrals *)
ee_ints : mo Four_idx_storage.t lazy_t; (* Electron-electron potential integrals *)
kin_ints : (mo,mo) Matrix.t lazy_t; (* Kinetic energy integrals *)
one_e_ints : (mo,mo) Matrix.t lazy_t; (* One-electron integrals *)
(* TODO
f12_ints : F12.t lazy_t; (* F12 integrals *)
*)
}
let size t =
Matrix.dim2 t.mo_coef
let simulation t = t.simulation
let mo_type t = t.mo_type
let ao_basis t = Si.ao_basis t.simulation
let mo_occupation t = t.mo_occupation
let mo_coef t = t.mo_coef
let eN_ints t = Lazy.force t.eN_ints
let ee_ints t = Lazy.force t.ee_ints
let kin_ints t = Lazy.force t.kin_ints
let two_e_ints t = Lazy.force t.ee_ints
(* TODO
let f12_ints t = Lazy.force t.f12_ints
*)
let one_e_ints t = Lazy.force t.one_e_ints
let mo_energies t =
let m_C = mo_coef t in
let f =
let m_N = Matrix.of_diag @@ mo_occupation t in
let m_P = Matrix.x_o_xt ~o:m_N ~x:m_C in
match t.mo_type with
| RHF -> Fock.make_rhf ~density:m_P (ao_basis t)
| Projected
| ROHF -> (Matrix.scale_inplace 0.5 m_P;
Fock.make_uhf ~density_same:m_P ~density_other:m_P (ao_basis t))
| _ -> failwith "Not implemented"
in
let m_F0 = Fock.fock f in
Matrix.xt_o_x ~o:m_F0 ~x:m_C
|> Matrix.diag
let mo_matrix_of_ao_matrix ~mo_coef ao_matrix =
Matrix.xt_o_x ~x:mo_coef ~o:ao_matrix
let ao_matrix_of_mo_matrix ~mo_coef ~ao_overlap mo_matrix =
let sc = Matrix.gemm ao_overlap mo_coef in
Matrix.x_o_xt ~x:sc ~o:mo_matrix
let make ~simulation ~mo_type ~mo_occupation ~mo_coef () =
let ao_basis =
Si.ao_basis simulation
in
let eN_ints = lazy (
Ao.Basis.eN_ints ao_basis
|> mo_matrix_of_ao_matrix ~mo_coef
)
and kin_ints = lazy (
Ao.Basis.kin_ints ao_basis
|> mo_matrix_of_ao_matrix ~mo_coef
)
and ee_ints = lazy (
Ao.Basis.ee_ints ao_basis
|> Four_idx_storage.four_index_transform mo_coef
)
(*
and f12_ints = lazy (
Ao.Basis.f12_ints ao_basis
|> F12.four_index_transform mo_coef
)
*)
in
let one_e_ints = lazy (
Matrix.add (Lazy.force eN_ints) (Lazy.force kin_ints) )
in
{ simulation ; mo_type ; mo_occupation ; mo_coef ;
eN_ints ; ee_ints ; kin_ints ; one_e_ints ;
}
let values t point =
let c = mo_coef t in
let a = Ao.Basis.values (Simulation.ao_basis t.simulation) point in
Matrix.gemv_t c a
let of_hartree_fock hf =
let mo_coef = HF.eigenvectors hf in
let simulation = HF.simulation hf in
let mo_occupation = HF.occupation hf in
let mo_type =
match HF.kind hf with
| HF.RHF -> RHF
| HF.ROHF -> ROHF
| HF.UHF -> UHF
in
make ~simulation ~mo_type ~mo_occupation ~mo_coef ()
(*
let of_mo_basis simulation other =
let mo_coef =
let basis = Simulation.ao_basis simulation in
let basis_other = ao_basis other in
let m_S =
Ao.Overlap.(of_basis_pair
(Ao.Basis.ao_basis basis)
(Ao.Basis.ao_basis basis_other) )
in
let m_X = Ao.Basis.ortho basis in
(* Project other vectors in the current basis *)
let m_C =
gemm m_S @@ mo_coef other
in
(* Append dummy vectors to the input vectors *)
let result =
let vecs = Mat.to_col_vecs m_X in
Array.iteri (fun i v -> if (i < Array.length vecs) then vecs.(i) <- v)
(Mat.to_col_vecs m_C) ;
Mat.of_col_vecs vecs
in
(* Gram-Schmidt Orthonormalization *)
gemm m_X @@ (Util.qr_ortho @@ gemm ~transa:`T m_X result)
|> Util.remove_epsilons
|> Conventions.rephase
in
let mo_occupation =
let occ = mo_occupation other in
Vec.init (Mat.dim2 mo_coef) (fun i ->
if (i <= Vec.dim occ) then occ.{i}
else 0.)
in
make ~simulation ~mo_type:Projected ~mo_occupation ~mo_coef ()
*)
let pp ?(start=1) ?(finish=0) ppf t =
let rows = Matrix.dim1 t.mo_coef
and cols = Matrix.dim2 t.mo_coef
in
let finish =
match finish with
| 0 -> cols
| x -> x
in
let rec aux first =
if (first > finish) then ()
else
begin
Format.fprintf ppf "@[<v>@[<v4>@[<h>%s@;" "Eigenvalues:";
Array.iteri (fun i x ->
if (i+1 >= first) && (i+1 <= first+4 ) then
Format.fprintf ppf "%12f@ " x)
(Vector.to_array @@ mo_energies t);
Format.fprintf ppf "@]@;";
Format.fprintf ppf "@[%a@]"
(Lacaml.Io.pp_lfmat
~row_labels:
(Array.init rows (fun i -> Printf.sprintf "%d " (i + 1)))
~col_labels:
(Array.init (min 5 (cols-first+1)) (fun i -> Printf.sprintf "-- %d --" (i + first) ))
~print_right:false
~print_foot:false
() ) (Matrix.to_bigarray_inplace t.mo_coef
|> Lacaml.D.lacpy ~ac:first ~n:(min 5 (cols-first+1)) ) ;
Format.fprintf ppf "@]@;@;@]";
(aux [@tailcall]) (first+5)
end
in
aux start