QuantumPackage/src/two_body_rdm/all_states_2_rdm.irp.f



 BEGIN_PROVIDER [double precision, all_states_act_two_rdm_alpha_alpha_mo, (n_act_orb,n_act_orb,n_act_orb,n_act_orb,N_states)]
 implicit none
 double precision, allocatable :: state_weights(:) 
 BEGIN_DOC
! all_states_act_two_rdm_alpha_alpha_mo(i,j,k,l) = state average physicist two-body rdm restricted to the ACTIVE indices for alpha-alpha electron pairs
!                                     = <Psi| a^{\dagger}_i a^{\dagger}_j a_l a_k |Psi>
 END_DOC 
 allocate(state_weights(N_states))
 state_weights = 1.d0/dble(N_states)
 integer :: ispin
 ! condition for alpha/beta spin
 ispin = 1 
 all_states_act_two_rdm_alpha_alpha_mo = 0.D0
 call orb_range_all_states_two_rdm(all_states_act_two_rdm_alpha_alpha_mo,n_act_orb,n_act_orb,list_act,list_act_reverse,ispin,psi_coef,size(psi_coef,2),size(psi_coef,1))

 END_PROVIDER 

 BEGIN_PROVIDER [double precision, all_states_act_two_rdm_beta_beta_mo, (n_act_orb,n_act_orb,n_act_orb,n_act_orb,N_states)]
 implicit none
 double precision, allocatable :: state_weights(:) 
 BEGIN_DOC
! all_states_act_two_rdm_beta_beta_mo(i,j,k,l) = state average physicist two-body rdm restricted to the ACTIVE indices for beta-beta electron pairs
!                                     = <Psi| a^{\dagger}_i a^{\dagger}_j a_l a_k |Psi>
 END_DOC 
 allocate(state_weights(N_states))
 state_weights = 1.d0/dble(N_states)
 integer :: ispin
 ! condition for alpha/beta spin
 ispin = 2
 all_states_act_two_rdm_beta_beta_mo = 0.d0
 call orb_range_all_states_two_rdm(all_states_act_two_rdm_beta_beta_mo,n_act_orb,n_act_orb,list_act,list_act_reverse,ispin,psi_coef,size(psi_coef,2),size(psi_coef,1))

 END_PROVIDER 

 BEGIN_PROVIDER [double precision, all_states_act_two_rdm_alpha_beta_mo, (n_act_orb,n_act_orb,n_act_orb,n_act_orb,N_states)]
 implicit none
 double precision, allocatable :: state_weights(:) 
 BEGIN_DOC
! all_states_act_two_rdm_alpha_beta_mo(i,j,k,l) = state average physicist two-body rdm restricted to the ACTIVE indices for alpha-beta electron pairs
!                                     = <Psi| a^{\dagger}_{i,alpha} a^{\dagger}_{j,beta} a_{l,beta} a_{k,alpha} |Psi>
 END_DOC 
 allocate(state_weights(N_states))
 state_weights = 1.d0/dble(N_states)
 integer :: ispin
 ! condition for alpha/beta spin
 print*,''
 print*,''
 print*,''
 print*,'providint all_states_act_two_rdm_alpha_beta_mo '
 ispin = 3 
 print*,'ispin = ',ispin
 all_states_act_two_rdm_alpha_beta_mo = 0.d0
 call orb_range_all_states_two_rdm(all_states_act_two_rdm_alpha_beta_mo,n_act_orb,n_act_orb,list_act,list_act_reverse,ispin,psi_coef,size(psi_coef,2),size(psi_coef,1))

 END_PROVIDER 


 BEGIN_PROVIDER [double precision, all_states_act_two_rdm_spin_trace_mo, (n_act_orb,n_act_orb,n_act_orb,n_act_orb,N_states)]
 implicit none
 BEGIN_DOC
! all_states_act_two_rdm_spin_trace_mo(i,j,k,l) = state average physicist spin trace two-body rdm restricted to the ACTIVE indices
! The active part of the two-electron energy can be computed as:
!
!   \sum_{i,j,k,l = 1, n_act_orb} all_states_act_two_rdm_spin_trace_mo(i,j,k,l) * < ii jj | kk ll > 
!
!   with ii = list_act(i), jj = list_act(j), kk = list_act(k), ll = list_act(l)
 END_DOC
 double precision, allocatable :: state_weights(:) 
 allocate(state_weights(N_states))
 state_weights = 1.d0/dble(N_states)
 integer :: ispin
 ! condition for alpha/beta spin
 ispin = 4 
 all_states_act_two_rdm_spin_trace_mo = 0.d0
 integer :: i

 call orb_range_all_states_two_rdm(all_states_act_two_rdm_spin_trace_mo,n_act_orb,n_act_orb,list_act,list_act_reverse,ispin,psi_coef,size(psi_coef,2),size(psi_coef,1))

 END_PROVIDER
renamed two-rdm for explicit separation between all states and state average 2019-07-01 17:49:31 +02:00


			`BEGIN_PROVIDER [double precision, all_states_act_two_rdm_alpha_alpha_mo, (n_act_orb,n_act_orb,n_act_orb,n_act_orb,N_states)]`
			`implicit none`
			`double precision, allocatable :: state_weights(:)`
			`BEGIN_DOC`
			`! all_states_act_two_rdm_alpha_alpha_mo(i,j,k,l) = state average physicist two-body rdm restricted to the ACTIVE indices for alpha-alpha electron pairs`
			`! = <Psi\| a^{\dagger}_i a^{\dagger}_j a_l a_k \|Psi>`
			`END_DOC`
			`allocate(state_weights(N_states))`
			`state_weights = 1.d0/dble(N_states)`
			`integer :: ispin`
			`! condition for alpha/beta spin`
			`ispin = 1`
			`all_states_act_two_rdm_alpha_alpha_mo = 0.D0`
beginning to rewrite two_rdm 2019-07-04 16:16:57 +02:00			`call orb_range_all_states_two_rdm(all_states_act_two_rdm_alpha_alpha_mo,n_act_orb,n_act_orb,list_act,list_act_reverse,ispin,psi_coef,size(psi_coef,2),size(psi_coef,1))`
renamed two-rdm for explicit separation between all states and state average 2019-07-01 17:49:31 +02:00
			`END_PROVIDER`

			`BEGIN_PROVIDER [double precision, all_states_act_two_rdm_beta_beta_mo, (n_act_orb,n_act_orb,n_act_orb,n_act_orb,N_states)]`
			`implicit none`
			`double precision, allocatable :: state_weights(:)`
			`BEGIN_DOC`
			`! all_states_act_two_rdm_beta_beta_mo(i,j,k,l) = state average physicist two-body rdm restricted to the ACTIVE indices for beta-beta electron pairs`
			`! = <Psi\| a^{\dagger}_i a^{\dagger}_j a_l a_k \|Psi>`
			`END_DOC`
			`allocate(state_weights(N_states))`
			`state_weights = 1.d0/dble(N_states)`
			`integer :: ispin`
			`! condition for alpha/beta spin`
			`ispin = 2`
			`all_states_act_two_rdm_beta_beta_mo = 0.d0`
beginning to rewrite two_rdm 2019-07-04 16:16:57 +02:00			`call orb_range_all_states_two_rdm(all_states_act_two_rdm_beta_beta_mo,n_act_orb,n_act_orb,list_act,list_act_reverse,ispin,psi_coef,size(psi_coef,2),size(psi_coef,1))`
renamed two-rdm for explicit separation between all states and state average 2019-07-01 17:49:31 +02:00
			`END_PROVIDER`

			`BEGIN_PROVIDER [double precision, all_states_act_two_rdm_alpha_beta_mo, (n_act_orb,n_act_orb,n_act_orb,n_act_orb,N_states)]`
			`implicit none`
			`double precision, allocatable :: state_weights(:)`
			`BEGIN_DOC`
			`! all_states_act_two_rdm_alpha_beta_mo(i,j,k,l) = state average physicist two-body rdm restricted to the ACTIVE indices for alpha-beta electron pairs`
			`! = <Psi\| a^{\dagger}_{i,alpha} a^{\dagger}_{j,beta} a_{l,beta} a_{k,alpha} \|Psi>`
			`END_DOC`
			`allocate(state_weights(N_states))`
			`state_weights = 1.d0/dble(N_states)`
			`integer :: ispin`
			`! condition for alpha/beta spin`
			`print*,''`
			`print*,''`
			`print*,''`
			`print*,'providint all_states_act_two_rdm_alpha_beta_mo '`
			`ispin = 3`
			`print*,'ispin = ',ispin`
			`all_states_act_two_rdm_alpha_beta_mo = 0.d0`
beginning to rewrite two_rdm 2019-07-04 16:16:57 +02:00			`call orb_range_all_states_two_rdm(all_states_act_two_rdm_alpha_beta_mo,n_act_orb,n_act_orb,list_act,list_act_reverse,ispin,psi_coef,size(psi_coef,2),size(psi_coef,1))`
renamed two-rdm for explicit separation between all states and state average 2019-07-01 17:49:31 +02:00
			`END_PROVIDER`


			`BEGIN_PROVIDER [double precision, all_states_act_two_rdm_spin_trace_mo, (n_act_orb,n_act_orb,n_act_orb,n_act_orb,N_states)]`
			`implicit none`
			`BEGIN_DOC`
			`! all_states_act_two_rdm_spin_trace_mo(i,j,k,l) = state average physicist spin trace two-body rdm restricted to the ACTIVE indices`
			`! The active part of the two-electron energy can be computed as:`
			`!`
			`! \sum_{i,j,k,l = 1, n_act_orb} all_states_act_two_rdm_spin_trace_mo(i,j,k,l) * < ii jj \| kk ll >`
			`!`
			`! with ii = list_act(i), jj = list_act(j), kk = list_act(k), ll = list_act(l)`
			`END_DOC`
			`double precision, allocatable :: state_weights(:)`
			`allocate(state_weights(N_states))`
			`state_weights = 1.d0/dble(N_states)`
			`integer :: ispin`
			`! condition for alpha/beta spin`
			`ispin = 4`
			`all_states_act_two_rdm_spin_trace_mo = 0.d0`
			`integer :: i`

beginning to rewrite two_rdm 2019-07-04 16:16:57 +02:00			`call orb_range_all_states_two_rdm(all_states_act_two_rdm_spin_trace_mo,n_act_orb,n_act_orb,list_act,list_act_reverse,ispin,psi_coef,size(psi_coef,2),size(psi_coef,1))`
renamed two-rdm for explicit separation between all states and state average 2019-07-01 17:49:31 +02:00
			`END_PROVIDER`