nano_mpi/src/velocity_module.F90

module velocity
  use parameter
  use simulation
  use definitions, ONLY: DP, NDIM
  use status, ONLY: error,info,warning
#ifdef MPI
  use mpi_module
#endif
  implicit none
  PRIVATE


  public :: calc_temp
  public :: quench
  public :: scale_velocities
  public :: randomize_velocities
  public :: remove_cm_momentum
  public :: remove_angular_momentum
  public :: get_com
  public :: get_com_all

contains

  subroutine quench()

    v = 0.0E0_DP

    call remove_cm_momentum()
    call remove_angular_momentum()

    return
  end subroutine quench

  subroutine scale_velocities(target_t)


    real( kind = DP ), intent(in) :: target_t
    integer :: i, dim
    real( kind = DP ) :: temperature
    real( kind = DP ) :: scaling


    call calc_temp(temperature)

    scaling = dsqrt(target_t / temperature)

   do i = 1, nlocal
       do dim = 1, ndim
          v(dim,i) = v(dim,i) * scaling
       end do
    end do

    call remove_cm_momentum()
    call remove_angular_momentum()

  end subroutine scale_velocities

!. ===============================================================================
  subroutine randomize_velocities(temperature)
    use model_module
    use constants, ONLY : twopi,pi
    use sprng_mod, ONLY : random_gauss
    real( kind = DP ), intent(in) :: temperature

    integer :: i, dim
    integer :: ntmp

    real( kind = DP ), allocatable, dimension(:) :: vbar

    real( kind = DP )                            :: mtmp,vbtmp
    real( kind = DP )                            :: vrand


    allocate(vbar(natypes))


    do i = 1, natypes
       if (is_atype(i)) then
          mtmp = atype_mass(i)
          vbar(i) = get_vbar(mtmp,temperature)
       endif
    enddo


    ! pick random velocity from gaussian distribution
    do i = 1, nlocal
       vbtmp = vbar(ident(i))
       v(1:ndim,i) = vbtmp * random_gauss()
    end do


    call remove_cm_momentum()
    call print_angular_momentum()
    call remove_angular_momentum()
    call print_angular_momentum()

    deallocate(vbar)
  end subroutine randomize_velocities

!.============================================================================================
! . write total angular momentum
  subroutine print_angular_momentum()
    use vectors, ONLY : cross_product
! . variables for 2-d angular momentum

! . varibles for 3-d angular momentum
    real( kind = DP ), dimension( ndim ) :: ltot
    real( kind = DP ), dimension( ndim ) :: l
    real( kind = DP ), dimension( ndim ) :: l_local
    real( kind = DP ), dimension( ndim ) :: r
    real( kind = DP ), dimension( ndim ) :: p

    real( kind = DP ), dimension( ndim ) :: com


    integer :: i
    character(len=80) :: msg

! . for single version natoms = nlocal

! . zero variables
    ltot     = 0.0_DP
    l_local  = 0.0_DP
    com      = 0.0_DP

! . get center of mass
    com = get_com()

    if (ndim /= 3) return

! . find angular momentum

! . handle 3-d case first
! . result is a vector

       do i = 1, nlocal
          r(1:ndim) = q(1:ndim,i) - com(1:ndim)
          p(1:ndim) = v(1:ndim,i)*mass(i)

          l = cross_product(r,p)

          l_local(1:ndim) = l_local(1:ndim) + l(1:ndim)
       end do

#ifdef MPI
       call mpi_allreduce(l_local,ltot,ndim,mpi_double_precision, &
            mpi_sum,mpi_comm_world,mpi_err)
       if (mpi_err /= 0) then
          call error("PRINT_ANGULAR_MOMENTUM", "MPI allreduce lx_local failed")
       endif
#else
       ltot = l_local
#endif
       write(msg,'(a6,3es12.3)') 'L = ', &
            ltot(1), ltot(2), ltot(3)
       call info('PRINT_ANGULAR_MOMENTUM',trim(msg))

       return


  end subroutine print_angular_momentum

!. =======================================================================================
! . Removes center of mass momentum
  subroutine remove_cm_momentum()
    integer :: i
    real( kind = dp ), dimension( ndim ) :: com_v


! . initialize center of mass velocity
    com_v = 0.0E0_DP

! . call get_com_v to get center of mass velocity
    com_v = get_com_v()

! . subtract center of mass momentum from velocity
    do i = 1, nlocal
       v(1:ndim,i) = v(1:ndim,i) - com_v(1:ndim)
    enddo

    return
  end subroutine remove_cm_momentum


  subroutine remove_angular_momentum()
    use f95_lapack,   only: la_getrf,la_getri
    use vectors,      only: cross_product
    integer :: i, j, k
    integer :: ifail,la_info
    character(len=80) :: junk
    real( kind = DP ) :: xx, yy, zz
    real( kind = DP ) :: xy, xz, yz

    real( kind = DP ),dimension(3,3)  :: inertia, inertia_save, identity
    real( kind = DP ),dimension(3,3)  :: inertia_inverse
    integer          ,dimension(3)    :: ipiv
    real( kind = DP), dimension(3)    :: angmom, omega, angmom_local
    real( kind = DP ),dimension(3)    :: this_q, this_v
    real( kind = DP ),dimension(9)    :: inertia_vec_local
    real( kind = DP ),dimension(9)    :: inertia_vec
    real( kind = DP ),dimension(3)    :: com, com_v
    real( kind = DP ),dimension(3,nlocal) :: q_adj_com, v_adj_com

! . if were not in 3-d, don't even bother

    if (ndim /= 3) then
       return
    end if

!. initialize center of mass
!. and velocity center of mass
    com   = 0.0E0_DP
    com_v = 0.0E0_DP

!    com   = get_com()
!    com_v = get_com_v()

! The get_com_all subroutine to avoid looping twice

    call get_com_all(com, com_v)
        
! . initialize components for inertia tensor
    xx=0.0_DP
    yy=0.0_DP
    zz=0.0_DP
    xy=0.0_DP
    xz=0.0_DP
    yz=0.0_DP

! . build components of Inertia tensor
!
!       [  Ixx -Ixy  -Ixz ]
!   J = | -Iyx  Iyy  -Iyz |
!       [ -Izx -Iyz   Izz ]
! See Fowles and Cassidy Chapter 9
! or Goldstein Chapter 5

!
    do i = 1, nlocal
       ! get components for this atom i.
       this_q(1:3) = q(1:3,i) - com(1:3)
       this_v(1:3) = v(1:3,i) - com_v(1:3)

       q_adj_com(1:3,i) = this_q(1:3)
       v_adj_com(1:3,i) = this_v(1:3)

! . compute moment of inertia coefficents
       xx = xx  + &
            this_q(1)*this_q(1)*mass(i)
       yy = yy  + &
            this_q(2)*this_q(2)*mass(i)
       zz = zz  + &
            this_q(3)*this_q(3)*mass(i)
! . compute products of inertia
       xy = xy  + &
            this_q(1)*this_q(2)*mass(i)
       xz = xz  + &
            this_q(1)*this_q(3)*mass(i)
       yz = yz  + &
            this_q(2)*this_q(3)*mass(i)

       angmom_local  = angmom_local + &
            cross_product(this_q,this_v) * mass(i)
    enddo

! . form the local inertia vector
! . f90 mpi won't allow a rank > 1 array in allreduce
! . so we make a vector length 9 and transfer it back
! . to a tensor after the allreduce
    inertia_vec_local(1)=yy+zz
    inertia_vec_local(2)=-xy
    inertia_vec_local(3)=-xz
    inertia_vec_local(4)=-xy
    inertia_vec_local(5)=xx+zz
    inertia_vec_local(6)=-yz
    inertia_vec_local(7)=-xz
    inertia_vec_local(8)=-yz
    inertia_vec_local(9)=xx+yy

! . Sum and distribute inertia and angmom arrays
#ifdef MPI
    call mpi_allreduce(inertia_vec_local,inertia_vec,9,mpi_double_precision, &
         mpi_sum,mpi_comm_world,mpi_err)
    if (mpi_err /= 0) then
       call error("REMOVE_ANGULAR_MOMENTUM", "MPI allreduce inertia_vec_local failed")
    endif

    call mpi_allreduce(angmom_local,angmom,3,mpi_double_precision, &
         mpi_sum,mpi_comm_world,mpi_err)
    if (mpi_err /= 0) then
       call error("REMOVE_ANGULAR_MOMENTUM", "MPI allreduce angmom_local failed")
    endif

    inertia(1,1) = inertia_vec(1)
    inertia(2,1) = inertia_vec(2)
    inertia(3,1) = inertia_vec(3)
    inertia(1,2) = inertia_vec(4)
    inertia(2,2) = inertia_vec(5)
    inertia(3,2) = inertia_vec(6)
    inertia(1,3) = inertia_vec(7)
    inertia(2,3) = inertia_vec(8)
    inertia(3,3) = inertia_vec(9)

#else
    inertia(1,1) = inertia_vec_local(1)
    inertia(2,1) = inertia_vec_local(2)
    inertia(3,1) = inertia_vec_local(3)
    inertia(1,2) = inertia_vec_local(4)
    inertia(2,2) = inertia_vec_local(5)
    inertia(3,2) = inertia_vec_local(6)
    inertia(1,3) = inertia_vec_local(7)
    inertia(2,3) = inertia_vec_local(8)
    inertia(3,3) = inertia_vec_local(9)

    angmom     = angmom_local
#endif

    ! invert the moment of inertia tensor by LU-decomposition / backsolving:

    call la_getrf(inertia, ipiv, INFO=la_info)
    if (la_info /= 0) then
       write(junk,*) 'LA_GETRF error in LU-Decomposition ',la_info
       call error('REMOVE_ANGULAR_MOMENTUM', &
            junk)
       
    end if

    call la_getri(inertia, ipiv, INFO=la_info)
    if (la_info /= 0) then
       call error('REMOVE_ANGULAR_MOMENTUM', &
            'LA_GETRI error in Inverting Moment of Inertia tensor')
    end if

    inertia_inverse = inertia

    ! calculate the angular velocities: omega = I^-1 . L

    omega = matmul(inertia_inverse, angmom)

    ! subtract out center of mass velocity and angular momentum from
    ! particle velocities

    do i = 1, nlocal
       this_q(1:3) = q_adj_com(1:3,i) 
       v(1:3,i) = v_adj_com(1:3,i) - cross_product(omega, this_q)
    enddo

    return
  end subroutine remove_angular_momentum

! ======================================================================================
!. functions
  function get_vbar(mass, this_temp) result(vbar)

    real( kind = DP )            :: vbar
    real( kind = DP ),intent(in) :: this_temp, mass
    real( kind = DP ), parameter :: kb = 1.381E-23_DP
    real( kind = DP ) :: kebar, vbar2


    kebar = 3.0E0_DP * kb * this_temp / 2.0E0_DP

    vbar2 = 2.0E0_DP * kebar / (mass * 1.661E-27_DP)

    vbar = dsqrt(vbar2/3.0E0_DP) * 1.0E-5_DP

    return
  end function get_vbar

subroutine calc_temp(this_temp,ke)
  use constants
  integer i, dim
  real( kind = DP ), intent(out)           :: this_temp
  real( kind = DP ), intent(out), optional :: ke
  real( kind = DP ) :: ktmp, converter, kebar, kb
  real( kind = DP ) :: ke_local
  real( kind = DP ) :: ke_global
  logical           :: do_ke

  do_ke = .false.
  if (present(ke)) do_ke = .true.

  converter = 1.0E0_DP/2.390664d3

  if (do_ke) ke = 0.0E0_DP
  ke_local = 0.0E0_DP
  this_temp = 0.0E0_DP
  ke_global = 0.0E0_DP

!  write(*,*) 'ndim: ',ndim
!  write(*,*) 'nlocal: ',nlocal

  do i = 1, nlocal
     ktmp = 0.0E0_DP
     do dim = 1, ndim
        ktmp = ktmp + v(dim,i)**2
     end do
     ke_local = ke_local + 0.5E0_DP * mass(i) * ktmp
  end do


#ifdef MPI
  call mpi_allreduce(ke_local,ke_global,1,mpi_double_precision, &
       mpi_sum,mpi_comm_world,mpi_err)
#else
  ke_global = ke_local
#endif

  ke_global = ke_global * AMUA2FS2_TO_KCALMOL

!  ke_global = ke_global/converter

  kebar = kcal_to_kj*1000.0E0_DP * ke_global / dble(natoms) / NAVOGADRO
!   kebar = 4.184E3_DP * ke_global / dble(natoms) / NAVOGADRO
  this_temp = 2.0E0_DP * kebar / (3.0E0_DP * K_BOLTZ)

  if (do_ke) ke = ke_global
  !  write(*,*) 'ke, kb, temp = ', ke, kb, temp

  return
end subroutine calc_temp

function get_com() result(com)
    real( kind = DP ), dimension( ndim ) :: com_local
    real( kind = DP ), dimension( ndim ) :: com
    integer :: i

    com = 0.0E0_DP
    com_local = 0.0E0_DP

    do i = 1, nlocal
       com_local(1:ndim) = com_local(1:ndim) + mass(i)*q(1:ndim,i)
    enddo

#ifdef MPI
    call mpi_allreduce(com_local,com,ndim,mpi_double_precision, &
         mpi_sum,mpi_comm_world,mpi_err)
    if (mpi_err /= 0) then
       call error("PRINT_ANGULAR_MOMENTUM", "MPI allreduce com failed")
    endif
#else
    com = com_local
#endif

    com(1:ndim) = com(1:ndim)/total_mass


    return

end function get_com


! . =============================================================================
              function get_com_v() result(com_v)
!. =============================================================================
!. returns center of mass velocity

    real( kind = DP ), dimension( ndim ) :: com_p_local
    real( kind = DP ), dimension( ndim ) :: com_p
    real( kind = DP ), dimension( ndim ) :: com_v
    integer :: i

    com_p = 0.0E0_DP
    com_p_local = 0.0E0_DP

    do i = 1, nlocal
       com_p_local(1:ndim) = com_p_local(1:ndim) + mass(i)*v(1:ndim,i)
    enddo

#ifdef MPI
    call mpi_allreduce(com_p_local,com_p,ndim,mpi_double_precision, &
         mpi_sum,mpi_comm_world,mpi_err)
    if (mpi_err /= 0) then
       call error("PRINT_ANGULAR_MOMENTUM", "MPI allreduce com failed")
    endif
#else
    com_p = com_p_local
#endif

    do i = 1, ndim
       com_v(i) = com_p(i)/total_mass
    enddo

    return

  end function get_com_v


!Maybe a subroutine to get com and com_v without looping twice

subroutine get_com_all(com, com_v)

    real( kind = DP ), dimension( ndim ) :: com_local
    real( kind = DP ), dimension( ndim ),intent(out) :: com
    real( kind = DP ), dimension( ndim ) :: com_p_local
    real( kind = DP ), dimension( ndim ) :: com_p
    real( kind = DP ), dimension( ndim ),intent(out) :: com_v
    integer :: i

    com = 0.0E0_DP
    com_local = 0.0E0_DP
    com_p = 0.0E0_DP
    com_p_local = 0.0E0_DP

    do i = 1, nlocal
       com_local(1:ndim) = com_local(1:ndim) + mass(i)*q(1:ndim,i)
       com_p_local(1:ndim) = com_p_local(1:ndim) + mass(i)*v(1:ndim,i)
    enddo

#ifdef MPI
    call mpi_allreduce(com_local,com,ndim,mpi_double_precision, &
         mpi_sum,mpi_comm_world,mpi_err)
    if (mpi_err /= 0) then
       call error("PRINT_ANGULAR_MOMENTUM", "MPI allreduce com failed")
    endif

    call mpi_allreduce(com_p_local,com_p,ndim,mpi_double_precision, &
         mpi_sum,mpi_comm_world,mpi_err)
    if (mpi_err /= 0) then
       call error("PRINT_ANGULAR_MOMENTUM", "MPI allreduce com failed")
    endif
#else
    com = com_local
    com_p = com_p_local
#endif

    com(1:ndim) = com(1:ndim)/total_mass
    com_v(1:ndim) = com_p(1:ndim)/total_mass

  return

end subroutine get_com_all

end module velocity
Revision:	9
Committed:	Mon Jul 1 15:27:33 2002 UTC (23 years, 4 months ago) by chuckv
File size:	13752 byte(s)
Log Message:	nose hoover chains added
#	User	Rev	Content
1	chuckv	4	module velocity
2			use parameter
3			use simulation
4			use definitions, ONLY: DP, NDIM
5			use status, ONLY: error,info,warning
6			#ifdef MPI
7			use mpi_module
8			#endif
9			implicit none
10			PRIVATE
11
12
13
14			public :: calc_temp
15			public :: quench
16			public :: scale_velocities
17			public :: randomize_velocities
18			public :: remove_cm_momentum
19			public :: remove_angular_momentum
20			public :: get_com
21			public :: get_com_all
22
23			contains
24
25			subroutine quench()
26
27			v = 0.0E0_DP
28
29			call remove_cm_momentum()
30			call remove_angular_momentum()
31
32			return
33			end subroutine quench
34
35			subroutine scale_velocities(target_t)
36
37
38			real( kind = DP ), intent(in) :: target_t
39			integer :: i, dim
40			real( kind = DP ) :: temperature
41			real( kind = DP ) :: scaling
42
43
44			call calc_temp(temperature)
45
46			scaling = dsqrt(target_t / temperature)
47
48			do i = 1, nlocal
49			do dim = 1, ndim
50			v(dim,i) = v(dim,i) * scaling
51			end do
52			end do
53
54			call remove_cm_momentum()
55			call remove_angular_momentum()
56
57			end subroutine scale_velocities
58
59			!. ===============================================================================
60			subroutine randomize_velocities(temperature)
61			use model_module
62			use constants, ONLY : twopi,pi
63			use sprng_mod, ONLY : random_gauss
64			real( kind = DP ), intent(in) :: temperature
65
66			integer :: i, dim
67			integer :: ntmp
68
69			real( kind = DP ), allocatable, dimension(:) :: vbar
70
71			real( kind = DP ) :: mtmp,vbtmp
72			real( kind = DP ) :: vrand
73
74
75
76
77			allocate(vbar(natypes))
78
79
80			do i = 1, natypes
81			if (is_atype(i)) then
82			mtmp = atype_mass(i)
83			vbar(i) = get_vbar(mtmp,temperature)
84			endif
85			enddo
86
87
88
89			! pick random velocity from gaussian distribution
90			do i = 1, nlocal
91			vbtmp = vbar(ident(i))
92			v(1:ndim,i) = vbtmp * random_gauss()
93			end do
94
95
96
97			call remove_cm_momentum()
98			call print_angular_momentum()
99			call remove_angular_momentum()
100			call print_angular_momentum()
101
102			deallocate(vbar)
103			end subroutine randomize_velocities
104
105			!.============================================================================================
106			! . write total angular momentum
107			subroutine print_angular_momentum()
108			use vectors, ONLY : cross_product
109			! . variables for 2-d angular momentum
110
111			! . varibles for 3-d angular momentum
112			real( kind = DP ), dimension( ndim ) :: ltot
113			real( kind = DP ), dimension( ndim ) :: l
114			real( kind = DP ), dimension( ndim ) :: l_local
115			real( kind = DP ), dimension( ndim ) :: r
116			real( kind = DP ), dimension( ndim ) :: p
117
118			real( kind = DP ), dimension( ndim ) :: com
119
120
121			integer :: i
122			character(len=80) :: msg
123
124			! . for single version natoms = nlocal
125
126			! . zero variables
127			ltot = 0.0_DP
128			l_local = 0.0_DP
129			com = 0.0_DP
130
131			! . get center of mass
132			com = get_com()
133
134			if (ndim /= 3) return
135
136			! . find angular momentum
137
138			! . handle 3-d case first
139			! . result is a vector
140
141			do i = 1, nlocal
142			r(1:ndim) = q(1:ndim,i) - com(1:ndim)
143			p(1:ndim) = v(1:ndim,i)*mass(i)
144
145			l = cross_product(r,p)
146
147			l_local(1:ndim) = l_local(1:ndim) + l(1:ndim)
148			end do
149
150			#ifdef MPI
151			call mpi_allreduce(l_local,ltot,ndim,mpi_double_precision, &
152			mpi_sum,mpi_comm_world,mpi_err)
153			if (mpi_err /= 0) then
154			call error("PRINT_ANGULAR_MOMENTUM", "MPI allreduce lx_local failed")
155			endif
156			#else
157			ltot = l_local
158			#endif
159			write(msg,'(a6,3es12.3)') 'L = ', &
160			ltot(1), ltot(2), ltot(3)
161			call info('PRINT_ANGULAR_MOMENTUM',trim(msg))
162
163			return
164
165
166			end subroutine print_angular_momentum
167
168			!. =======================================================================================
169			! . Removes center of mass momentum
170			subroutine remove_cm_momentum()
171			integer :: i
172			real( kind = dp ), dimension( ndim ) :: com_v
173
174
175
176			! . initialize center of mass velocity
177			com_v = 0.0E0_DP
178
179			! . call get_com_v to get center of mass velocity
180			com_v = get_com_v()
181
182			! . subtract center of mass momentum from velocity
183			do i = 1, nlocal
184			v(1:ndim,i) = v(1:ndim,i) - com_v(1:ndim)
185			enddo
186
187			return
188			end subroutine remove_cm_momentum
189
190
191
192
193			subroutine remove_angular_momentum()
194			use f95_lapack, only: la_getrf,la_getri
195			use vectors, only: cross_product
196			integer :: i, j, k
197			integer :: ifail,la_info
198	chuckv	9	character(len=80) :: junk
199	chuckv	4	real( kind = DP ) :: xx, yy, zz
200			real( kind = DP ) :: xy, xz, yz
201
202			real( kind = DP ),dimension(3,3) :: inertia, inertia_save, identity
203			real( kind = DP ),dimension(3,3) :: inertia_inverse
204			integer ,dimension(3) :: ipiv
205			real( kind = DP), dimension(3) :: angmom, omega, angmom_local
206			real( kind = DP ),dimension(3) :: this_q, this_v
207			real( kind = DP ),dimension(9) :: inertia_vec_local
208			real( kind = DP ),dimension(9) :: inertia_vec
209			real( kind = DP ),dimension(3) :: com, com_v
210			real( kind = DP ),dimension(3,nlocal) :: q_adj_com, v_adj_com
211
212			! . if were not in 3-d, don't even bother
213
214			if (ndim /= 3) then
215			return
216			end if
217
218			!. initialize center of mass
219			!. and velocity center of mass
220			com = 0.0E0_DP
221			com_v = 0.0E0_DP
222
223			! com = get_com()
224			! com_v = get_com_v()
225
226			! The get_com_all subroutine to avoid looping twice
227
228			call get_com_all(com, com_v)
229
230			! . initialize components for inertia tensor
231			xx=0.0_DP
232			yy=0.0_DP
233			zz=0.0_DP
234			xy=0.0_DP
235			xz=0.0_DP
236			yz=0.0_DP
237
238			! . build components of Inertia tensor
239			!
240			! [ Ixx -Ixy -Ixz ]
241			! J = \| -Iyx Iyy -Iyz \|
242			! [ -Izx -Iyz Izz ]
243			! See Fowles and Cassidy Chapter 9
244			! or Goldstein Chapter 5
245
246			!
247			do i = 1, nlocal
248			! get components for this atom i.
249			this_q(1:3) = q(1:3,i) - com(1:3)
250			this_v(1:3) = v(1:3,i) - com_v(1:3)
251
252			q_adj_com(1:3,i) = this_q(1:3)
253			v_adj_com(1:3,i) = this_v(1:3)
254
255			! . compute moment of inertia coefficents
256			xx = xx + &
257			this_q(1)this_q(1)mass(i)
258			yy = yy + &
259			this_q(2)this_q(2)mass(i)
260			zz = zz + &
261			this_q(3)this_q(3)mass(i)
262			! . compute products of inertia
263			xy = xy + &
264			this_q(1)this_q(2)mass(i)
265			xz = xz + &
266			this_q(1)this_q(3)mass(i)
267			yz = yz + &
268			this_q(2)this_q(3)mass(i)
269
270			angmom_local = angmom_local + &
271			cross_product(this_q,this_v) * mass(i)
272			enddo
273
274			! . form the local inertia vector
275			! . f90 mpi won't allow a rank > 1 array in allreduce
276			! . so we make a vector length 9 and transfer it back
277			! . to a tensor after the allreduce
278			inertia_vec_local(1)=yy+zz
279			inertia_vec_local(2)=-xy
280			inertia_vec_local(3)=-xz
281			inertia_vec_local(4)=-xy
282			inertia_vec_local(5)=xx+zz
283			inertia_vec_local(6)=-yz
284			inertia_vec_local(7)=-xz
285			inertia_vec_local(8)=-yz
286			inertia_vec_local(9)=xx+yy
287
288			! . Sum and distribute inertia and angmom arrays
289			#ifdef MPI
290			call mpi_allreduce(inertia_vec_local,inertia_vec,9,mpi_double_precision, &
291			mpi_sum,mpi_comm_world,mpi_err)
292			if (mpi_err /= 0) then
293			call error("REMOVE_ANGULAR_MOMENTUM", "MPI allreduce inertia_vec_local failed")
294			endif
295
296			call mpi_allreduce(angmom_local,angmom,3,mpi_double_precision, &
297			mpi_sum,mpi_comm_world,mpi_err)
298			if (mpi_err /= 0) then
299			call error("REMOVE_ANGULAR_MOMENTUM", "MPI allreduce angmom_local failed")
300			endif
301
302			inertia(1,1) = inertia_vec(1)
303			inertia(2,1) = inertia_vec(2)
304			inertia(3,1) = inertia_vec(3)
305			inertia(1,2) = inertia_vec(4)
306			inertia(2,2) = inertia_vec(5)
307			inertia(3,2) = inertia_vec(6)
308			inertia(1,3) = inertia_vec(7)
309			inertia(2,3) = inertia_vec(8)
310			inertia(3,3) = inertia_vec(9)
311
312			#else
313			inertia(1,1) = inertia_vec_local(1)
314			inertia(2,1) = inertia_vec_local(2)
315			inertia(3,1) = inertia_vec_local(3)
316			inertia(1,2) = inertia_vec_local(4)
317			inertia(2,2) = inertia_vec_local(5)
318			inertia(3,2) = inertia_vec_local(6)
319			inertia(1,3) = inertia_vec_local(7)
320			inertia(2,3) = inertia_vec_local(8)
321			inertia(3,3) = inertia_vec_local(9)
322
323			angmom = angmom_local
324			#endif
325
326			! invert the moment of inertia tensor by LU-decomposition / backsolving:
327
328	chuckv	9	call la_getrf(inertia, ipiv, INFO=la_info)
329	chuckv	4	if (la_info /= 0) then
330	chuckv	9	write(junk,*) 'LA_GETRF error in LU-Decomposition ',la_info
331	chuckv	4	call error('REMOVE_ANGULAR_MOMENTUM', &
332	chuckv	9	junk)
333
334	chuckv	4	end if
335
336			call la_getri(inertia, ipiv, INFO=la_info)
337			if (la_info /= 0) then
338			call error('REMOVE_ANGULAR_MOMENTUM', &
339			'LA_GETRI error in Inverting Moment of Inertia tensor')
340			end if
341
342			inertia_inverse = inertia
343
344			! calculate the angular velocities: omega = I^-1 . L
345
346			omega = matmul(inertia_inverse, angmom)
347
348			! subtract out center of mass velocity and angular momentum from
349			! particle velocities
350
351			do i = 1, nlocal
352			this_q(1:3) = q_adj_com(1:3,i)
353			v(1:3,i) = v_adj_com(1:3,i) - cross_product(omega, this_q)
354			enddo
355
356			return
357			end subroutine remove_angular_momentum
358
359			! ======================================================================================
360			!. functions
361			function get_vbar(mass, this_temp) result(vbar)
362
363			real( kind = DP ) :: vbar
364			real( kind = DP ),intent(in) :: this_temp, mass
365			real( kind = DP ), parameter :: kb = 1.381E-23_DP
366			real( kind = DP ) :: kebar, vbar2
367
368
369			kebar = 3.0E0_DP * kb * this_temp / 2.0E0_DP
370
371			vbar2 = 2.0E0_DP * kebar / (mass * 1.661E-27_DP)
372
373			vbar = dsqrt(vbar2/3.0E0_DP) * 1.0E-5_DP
374
375			return
376			end function get_vbar
377
378			subroutine calc_temp(this_temp,ke)
379			use constants
380			integer i, dim
381			real( kind = DP ), intent(out) :: this_temp
382			real( kind = DP ), intent(out), optional :: ke
383			real( kind = DP ) :: ktmp, converter, kebar, kb
384			real( kind = DP ) :: ke_local
385			real( kind = DP ) :: ke_global
386			logical :: do_ke
387
388			do_ke = .false.
389			if (present(ke)) do_ke = .true.
390
391			converter = 1.0E0_DP/2.390664d3
392
393			if (do_ke) ke = 0.0E0_DP
394			ke_local = 0.0E0_DP
395			this_temp = 0.0E0_DP
396			ke_global = 0.0E0_DP
397
398	chuckv	9	! write(,) 'ndim: ',ndim
399			! write(,) 'nlocal: ',nlocal
400
401	chuckv	4	do i = 1, nlocal
402			ktmp = 0.0E0_DP
403			do dim = 1, ndim
404			ktmp = ktmp + v(dim,i)**2
405			end do
406			ke_local = ke_local + 0.5E0_DP * mass(i) * ktmp
407			end do
408
409
410
411			#ifdef MPI
412			call mpi_allreduce(ke_local,ke_global,1,mpi_double_precision, &
413			mpi_sum,mpi_comm_world,mpi_err)
414			#else
415			ke_global = ke_local
416			#endif
417
418			ke_global = ke_global * AMUA2FS2_TO_KCALMOL
419
420			! ke_global = ke_global/converter
421
422			kebar = kcal_to_kj1000.0E0_DP ke_global / dble(natoms) / NAVOGADRO
423			! kebar = 4.184E3_DP * ke_global / dble(natoms) / NAVOGADRO
424			this_temp = 2.0E0_DP * kebar / (3.0E0_DP * K_BOLTZ)
425
426			if (do_ke) ke = ke_global
427			! write(,) 'ke, kb, temp = ', ke, kb, temp
428
429			return
430			end subroutine calc_temp
431
432			function get_com() result(com)
433			real( kind = DP ), dimension( ndim ) :: com_local
434			real( kind = DP ), dimension( ndim ) :: com
435			integer :: i
436
437			com = 0.0E0_DP
438			com_local = 0.0E0_DP
439
440			do i = 1, nlocal
441			com_local(1:ndim) = com_local(1:ndim) + mass(i)*q(1:ndim,i)
442			enddo
443
444			#ifdef MPI
445			call mpi_allreduce(com_local,com,ndim,mpi_double_precision, &
446			mpi_sum,mpi_comm_world,mpi_err)
447			if (mpi_err /= 0) then
448			call error("PRINT_ANGULAR_MOMENTUM", "MPI allreduce com failed")
449			endif
450			#else
451			com = com_local
452			#endif
453
454			com(1:ndim) = com(1:ndim)/total_mass
455
456
457			return
458
459			end function get_com
460
461
462			! . =============================================================================
463			function get_com_v() result(com_v)
464			!. =============================================================================
465			!. returns center of mass velocity
466
467			real( kind = DP ), dimension( ndim ) :: com_p_local
468			real( kind = DP ), dimension( ndim ) :: com_p
469			real( kind = DP ), dimension( ndim ) :: com_v
470			integer :: i
471
472			com_p = 0.0E0_DP
473			com_p_local = 0.0E0_DP
474
475			do i = 1, nlocal
476			com_p_local(1:ndim) = com_p_local(1:ndim) + mass(i)*v(1:ndim,i)
477			enddo
478
479			#ifdef MPI
480			call mpi_allreduce(com_p_local,com_p,ndim,mpi_double_precision, &
481			mpi_sum,mpi_comm_world,mpi_err)
482			if (mpi_err /= 0) then
483			call error("PRINT_ANGULAR_MOMENTUM", "MPI allreduce com failed")
484			endif
485			#else
486			com_p = com_p_local
487			#endif
488
489			do i = 1, ndim
490			com_v(i) = com_p(i)/total_mass
491			enddo
492
493			return
494
495			end function get_com_v
496
497
498			!Maybe a subroutine to get com and com_v without looping twice
499
500			subroutine get_com_all(com, com_v)
501
502			real( kind = DP ), dimension( ndim ) :: com_local
503			real( kind = DP ), dimension( ndim ),intent(out) :: com
504			real( kind = DP ), dimension( ndim ) :: com_p_local
505			real( kind = DP ), dimension( ndim ) :: com_p
506			real( kind = DP ), dimension( ndim ),intent(out) :: com_v
507			integer :: i
508
509			com = 0.0E0_DP
510			com_local = 0.0E0_DP
511			com_p = 0.0E0_DP
512			com_p_local = 0.0E0_DP
513
514			do i = 1, nlocal
515			com_local(1:ndim) = com_local(1:ndim) + mass(i)*q(1:ndim,i)
516			com_p_local(1:ndim) = com_p_local(1:ndim) + mass(i)*v(1:ndim,i)
517			enddo
518
519			#ifdef MPI
520			call mpi_allreduce(com_local,com,ndim,mpi_double_precision, &
521			mpi_sum,mpi_comm_world,mpi_err)
522			if (mpi_err /= 0) then
523			call error("PRINT_ANGULAR_MOMENTUM", "MPI allreduce com failed")
524			endif
525
526			call mpi_allreduce(com_p_local,com_p,ndim,mpi_double_precision, &
527			mpi_sum,mpi_comm_world,mpi_err)
528			if (mpi_err /= 0) then
529			call error("PRINT_ANGULAR_MOMENTUM", "MPI allreduce com failed")
530			endif
531			#else
532			com = com_local
533			com_p = com_p_local
534			#endif
535
536			com(1:ndim) = com(1:ndim)/total_mass
537			com_v(1:ndim) = com_p(1:ndim)/total_mass
538
539			return
540
541			end subroutine get_com_all
542
543			end module velocity