mdtools/md_code/f_verlet_constrained.f

      subroutine v_constrain_a(dt,natoms,mass,rx,ry,rz,
     +     vx,vy,vz,fx,fy,fz, n_constrained, constraints_sqr, c_i, c_j, 
     +     box_x, box_y, box_z)
      implicit none
c     !   *******************************************************************
c     !   ** FIRST PART OF VELOCITY VERLET ALGORITHM                       **
c     !   **                                                               **
c     !   ** USAGE:                                                        **
c     !   **                                                               **
c     !   ** THE FIRST PART OF THE ALGORITHM IS A TAYLOR SERIES WHICH      **
c     !   ** ADVANCES POSITIONS FROM T TO T + DT AND VELOCITIES FROM       **
c     !   ** T TO T + DT/2.  AFTER THIS, THE FORCE ROUTINE IS CALLED.      **
c     !   *******************************************************************
      
      
c     ! move part a calculate velocities
      
      INTEGER     I
      double precision DT2, DTSQ2
      
      double precision box_x, box_y, box_z
  
c     !Global Parameters
      
      INTEGER  maxn,ndim,max_dim
      parameter  (maxn=2048,ndim=3,max_dim=3)
      INTEGER  natoms
  
c     !Global arrays
  
      double precision mass(natoms)
      double precision RX(natoms), RY(natoms), RZ(natoms) !Position
      double precision VX(natoms), VY(natoms), VZ(natoms) !Velocity
      double precision FX(natoms), FY(natoms), FZ(natoms) !force
    
c     ! Paramaters for force subroutines
  
      double precision dt
  
c     variables for the constraint methods

      integer n_constrained
      integer c_i(n_constrained), c_j(n_constrained)
      double precision constraints_sqr(n_constrained)
      logical done
      logical moving(natoms), moved(natoms)
      double precision rptol, tol, tol2
      double precision pxab, pyab, pzab, pabsq, rabsq, diffsq
      double precision rxab, ryab, rzab, rpab, gab
      double precision dx, dy, dz, rma, rmb
      integer a, b, it, maxit
      parameter (rptol = 1.0d-6, tol = 1.0d-6 )
      parameter ( maxit = 100 )

      double precision px(natoms), py(natoms), pz(natoms)
      
      double precision e_convert
      parameter ( e_convert = 4.184d-4 )
  
        
      DT2   = DT / 2.0d0
      DTSQ2 = DT * DT2
      
      DO I = 1, natoms
         
         px(I) = RX(I) + DT * VX(I) + 
     +        (DTSQ2 * FX(I) * e_convert / mass(i))
         py(I) = RY(I) + DT * VY(I) + 
     +        (DTSQ2 * FY(I) * e_convert / mass(i))
         pz(I) = RZ(I) + DT * VZ(I) + 
     +        (DTSQ2 * FZ(I) * e_convert / mass(i))
         VX(I) = VX(I) + (DT2 * FX(I) * e_convert / mass(i))
         VY(I) = VY(I) + (DT2 * FY(I) * e_convert / mass(i))
         VZ(I) = VZ(I) + (DT2 * FZ(I) * e_convert / mass(i))
         
         moving(i) = .false.
         moved(i) = .true.
         
      end do

      it = 0
      done = .false.

c     start iterative loop

      do while( (.not. done) .and. (it .le. maxit))
         
         done = .true.

         do i = 1, n_constrained
            
            a = c_i(i)
            b = c_j(i)
            
            if( moved(a) .or. moved(b) ) then
               
               pxab = px(a) - px(b)
               pyab = py(a) - py(b)
               pzab = pz(a) - pz(b)

               pxab = pxab - box_x * dsign( 1.0d0, pxab )
     +              * int( dabs( pxab / box_x ) + 0.5d0 )
               pyab = pyab - box_y * dsign( 1.0d0, pyab )
     +              * int( dabs( pyab / box_y ) + 0.5d0 )
               pzab = pzab - box_z * dsign( 1.0d0, pzab )
     +              * int( dabs( pzab / box_z ) + 0.5d0 )

               
               pabsq = pxab * pxab + pyab * pyab + pzab * pzab
               rabsq = constraints_sqr(i)
               diffsq = rabsq - pabsq
C               write ( *,* )diffsq

               if( dabs(diffsq) .gt. tol ) then
                  
                  rxab = rx(a) - rx(b)                  
                  ryab = ry(a) - ry(b)                  
                  rzab = rz(a) - rz(b)
                  
                  rxab = rxab - box_x * dsign( 1.0d0, rxab )
     +                 * int( dabs( rxab / box_x ) + 0.5d0 )
                  ryab = ryab - box_y * dsign( 1.0d0, ryab )
     +                 * int( dabs( ryab / box_y ) + 0.5d0 )
                  rzab = rzab - box_z * dsign( 1.0d0, rzab )
     +                 * int( dabs( rzab / box_z ) + 0.5d0 )

                  rpab = rxab * pxab + ryab * pyab + rzab * pzab
                  
                  if( dabs(rpab) .lt. ( rabsq * rptol ) ) then
                     write (*, '('' Constraint Failure '')' )
                     write (*,*) a-1, b-1,rpab, rabsq * rptol
                     stop
                  end if

                  rma = 1.0d0 / mass(a)
                  rmb = 1.0d0 / mass(b)

                  gab = diffsq / ( 2.0d0 * ( rma + rmb ) * rpab )
                  dx = rxab * gab
                  dy = ryab * gab
                  dz = rzab * gab

                  px(a) = px(a) + rma * dx
                  py(a) = py(a) + rma * dy
                  pz(a) = pz(a) + rma * dz

                  px(b) = px(b) - rmb * dx
                  py(b) = py(b) - rmb * dy
                  pz(b) = pz(b) - rmb * dz
                  
                  dx = dx / dt
                  dy = dy / dt
                  dz = dz / dt

                  vx(a) = vx(a) + rma * dx
                  vy(a) = vy(a) + rma * dy
                  vz(a) = vz(a) + rma * dz

                  vx(b) = vx(b) - rmb * dx
                  vy(b) = vy(b) - rmb * dy
                  vz(b) = vz(b) - rmb * dz

                  moving(a) = .true.
                  moving(b) = .true.
                  done = .false.
                  
               endif
            endif
            
         enddo
      
         do i = 1, natoms
            moved(i) = moving(i)
            moving(i) = .false.
         enddo
         
         it = it + 1
      enddo

c     end of iterative loop

      if( .not. done) then
         write (*, '('' too many constraint iterations in move_a '')' )
         stop
      endif

c     store new values

      do i = 1, natoms
         rx(i) = px(i)
         ry(i) = py(i)
         rz(i) = pz(i)
      enddo

      
      RETURN
      end subroutine v_constrain_a
      

      Subroutine v_constrain_b(dt,natoms,mass,rx,ry,rz,
     +     vx,vy,vz,fx,fy,fz,k, n_constrained, constraints_sqr, 
     +     c_i, c_j, box_x, box_y, box_z)
      implicit none
  
c     !  *******************************************************************
c     !  ** SECOND PART OF VELOCITY VERLET ALGORITHM                      **
c     !  **                                                               **
c     !  ** USAGE:                                                        **
c     !  **                                                               **
c     !  ** THE SECOND PART OF THE ALGORITHM ADVANCES VELOCITIES FROM     **
c     !  ** T + DT/2 TO T + DT. THIS ASSUMES THAT FORCES HAVE BEEN        **
c     !  ** COMPUTED IN THE FORCE ROUTINE AND STORED IN FX, FY, FZ.       **
c     !  *******************************************************************
  
c     ! declarations
  
      integer  i
      double precision accvel2, dt2
      double precision box_x, box_y, box_z
  
c     !Global Parameters
  

      INTEGER natoms
  
c     !Global arrays
  
      double precision  mass(natoms)
      double precision RX(natoms), RY(natoms), RZ(natoms)  !position
      double precision VX(natoms), VY(natoms), VZ(natoms)  !velocity
      double precision  FX(natoms), FY(natoms), FZ(natoms) !force
  
  
c     ! Declaration for the kinetic energy
  
      double precision k
  
c     ! Paramaters for force subroutines
    
      double precision dt

c     constraint parameters and variables

      double precision tol, rxab, ryab, rzab, gab

      double precision vxab, vyab, vzab, dx, dy, dz, rma, rmb, rvab
      integer a, b, it, maxit, n_constrained
      parameter ( maxit = 100 )
      logical done
      logical moving(natoms), moved(natoms)
      integer c_i(n_constrained), c_j(n_constrained)
      double precision constraints_sqr(n_constrained)
      
      double precision e_convert
      parameter ( e_convert = 4.184d-4 )


c     ! *******************************************************************

      tol = 1.0d-6 / dt
      dt2 = dt / 2.0d0
      accvel2 = 0.0d0
      k = 0.0d0
      DO i = 1, natoms
         
         VX(I) = VX(I) + (DT2 * FX(I) * e_convert / mass(i))
         VY(I) = VY(I) + (DT2 * FY(I) * e_convert / mass(i))
         VZ(I) = VZ(I) + (DT2 * FZ(I) * e_convert / mass(i))

         moving(i) = .false.
         moved(i) = .true.
      enddo

      it = 0
      done = .false.
      
      do while( (.not. done) .and. ( it .le. maxit) )
         
         done = .true.
         
         do i=1, n_constrained
            
            a = c_i(i)
            b = c_j(i)

            if( moved(a) .or. moved(b) ) then
               
               vxab = vx(a) - vx(b)
               vyab = vy(a) - vy(b)
               vzab = vz(a) - vz(b)

               rxab = rx(a) - rx(b)
               ryab = ry(a) - ry(b)
               rzab = rz(a) - rz(b)
               
               rxab = rxab - box_x * dsign( 1.0d0, rxab )
     +              * int( dabs( rxab / box_x ) + 0.5d0 )
               ryab = ryab - box_y * dsign( 1.0d0, ryab )
     +              * int( dabs( ryab / box_y ) + 0.5d0 )
               rzab = rzab - box_z * dsign( 1.0d0, rzab )
     +              * int( dabs( rzab / box_z ) + 0.5d0 )
               
               
               rma = 1.0d0 / mass(a)
               rmb = 1.0d0 / mass(b)

               rvab = rxab * vxab + ryab * vyab + rzab * vzab

               gab = -rvab / ( ( rma + rmb ) * constraints_sqr(i) )

               if ( dabs(gab) .gt. tol) then
                  
                  dx = rxab * gab
                  dy = ryab * gab
                  dz = rzab * gab

                  vx(a) = vx(a) + rma * dx
                  vy(a) = vy(a) + rma * dy
                  vz(a) = vz(a) + rma * dz

                  vx(b) = vx(b) - rmb * dx
                  vy(b) = vy(b) - rmb * dy
                  vz(b) = vz(b) - rmb * dz

                  moving(a) = .true.
                  moving(b) = .true.
                  done = .false.
                  
               endif
               
            endif

         enddo

         do i = 1, natoms
            
            moved(i) = moving(i)
            moving(i) = .false.
            
         enddo

         it = it + 1
      
      enddo

c     End of iterative loop
      
      if (.not. done) then

         write(*, '('' Too many constraint iterations in moveb '')')
         stop

      endif
      
      do i = 1, natoms
         
         accvel2 = VX(I) ** 2 + VY(I) ** 2 + VZ(I) ** 2
         k = k + 0.5d0 * mass(i) * accvel2 / e_convert
         
      end do
  
  
      end subroutine v_constrain_b
Revision:	10
Committed:	Tue Jul 9 18:40:59 2002 UTC (23 years, 3 months ago) by mmeineke
Original Path:	*branches/mmeineke/mdtools/md_code/f_verlet_constrained.f*
File size:	11048 byte(s)
Log Message:	everything you need to make libmdtools
#	User	Rev	Content
1	mmeineke	10	subroutine v_constrain_a(dt,natoms,mass,rx,ry,rz,
2			+ vx,vy,vz,fx,fy,fz, n_constrained, constraints_sqr, c_i, c_j,
3			+ box_x, box_y, box_z)
4			implicit none
5			c ! *******************************************************************
6			c ! FIRST PART OF VELOCITY VERLET ALGORITHM
7			c !
8			c ! USAGE:
9			c !
10			c ! THE FIRST PART OF THE ALGORITHM IS A TAYLOR SERIES WHICH
11			c ! ADVANCES POSITIONS FROM T TO T + DT AND VELOCITIES FROM
12			c ! T TO T + DT/2. AFTER THIS, THE FORCE ROUTINE IS CALLED.
13			c ! *******************************************************************
14
15
16			c ! move part a calculate velocities
17
18			INTEGER I
19			double precision DT2, DTSQ2
20
21			double precision box_x, box_y, box_z
22
23			c !Global Parameters
24
25			INTEGER maxn,ndim,max_dim
26			parameter (maxn=2048,ndim=3,max_dim=3)
27			INTEGER natoms
28
29			c !Global arrays
30
31			double precision mass(natoms)
32			double precision RX(natoms), RY(natoms), RZ(natoms) !Position
33			double precision VX(natoms), VY(natoms), VZ(natoms) !Velocity
34			double precision FX(natoms), FY(natoms), FZ(natoms) !force
35
36			c ! Paramaters for force subroutines
37
38			double precision dt
39
40			c variables for the constraint methods
41
42			integer n_constrained
43			integer c_i(n_constrained), c_j(n_constrained)
44			double precision constraints_sqr(n_constrained)
45			logical done
46			logical moving(natoms), moved(natoms)
47			double precision rptol, tol, tol2
48			double precision pxab, pyab, pzab, pabsq, rabsq, diffsq
49			double precision rxab, ryab, rzab, rpab, gab
50			double precision dx, dy, dz, rma, rmb
51			integer a, b, it, maxit
52			parameter (rptol = 1.0d-6, tol = 1.0d-6 )
53			parameter ( maxit = 100 )
54
55			double precision px(natoms), py(natoms), pz(natoms)
56
57			double precision e_convert
58			parameter ( e_convert = 4.184d-4 )
59
60
61			DT2 = DT / 2.0d0
62			DTSQ2 = DT * DT2
63
64			DO I = 1, natoms
65
66			px(I) = RX(I) + DT * VX(I) +
67			+ (DTSQ2 * FX(I) * e_convert / mass(i))
68			py(I) = RY(I) + DT * VY(I) +
69			+ (DTSQ2 * FY(I) * e_convert / mass(i))
70			pz(I) = RZ(I) + DT * VZ(I) +
71			+ (DTSQ2 * FZ(I) * e_convert / mass(i))
72			VX(I) = VX(I) + (DT2 * FX(I) * e_convert / mass(i))
73			VY(I) = VY(I) + (DT2 * FY(I) * e_convert / mass(i))
74			VZ(I) = VZ(I) + (DT2 * FZ(I) * e_convert / mass(i))
75
76			moving(i) = .false.
77			moved(i) = .true.
78
79			end do
80
81			it = 0
82			done = .false.
83
84			c start iterative loop
85
86			do while( (.not. done) .and. (it .le. maxit))
87
88			done = .true.
89
90			do i = 1, n_constrained
91
92			a = c_i(i)
93			b = c_j(i)
94
95			if( moved(a) .or. moved(b) ) then
96
97			pxab = px(a) - px(b)
98			pyab = py(a) - py(b)
99			pzab = pz(a) - pz(b)
100
101			pxab = pxab - box_x * dsign( 1.0d0, pxab )
102			+ * int( dabs( pxab / box_x ) + 0.5d0 )
103			pyab = pyab - box_y * dsign( 1.0d0, pyab )
104			+ * int( dabs( pyab / box_y ) + 0.5d0 )
105			pzab = pzab - box_z * dsign( 1.0d0, pzab )
106			+ * int( dabs( pzab / box_z ) + 0.5d0 )
107
108
109			pabsq = pxab * pxab + pyab * pyab + pzab * pzab
110			rabsq = constraints_sqr(i)
111			diffsq = rabsq - pabsq
112			C write ( , )diffsq
113
114			if( dabs(diffsq) .gt. tol ) then
115
116			rxab = rx(a) - rx(b)
117			ryab = ry(a) - ry(b)
118			rzab = rz(a) - rz(b)
119
120			rxab = rxab - box_x * dsign( 1.0d0, rxab )
121			+ * int( dabs( rxab / box_x ) + 0.5d0 )
122			ryab = ryab - box_y * dsign( 1.0d0, ryab )
123			+ * int( dabs( ryab / box_y ) + 0.5d0 )
124			rzab = rzab - box_z * dsign( 1.0d0, rzab )
125			+ * int( dabs( rzab / box_z ) + 0.5d0 )
126
127			rpab = rxab * pxab + ryab * pyab + rzab * pzab
128
129			if( dabs(rpab) .lt. ( rabsq * rptol ) ) then
130			write (*, '('' Constraint Failure '')' )
131			write (,) a-1, b-1,rpab, rabsq * rptol
132			stop
133			end if
134
135			rma = 1.0d0 / mass(a)
136			rmb = 1.0d0 / mass(b)
137
138			gab = diffsq / ( 2.0d0 * ( rma + rmb ) * rpab )
139			dx = rxab * gab
140			dy = ryab * gab
141			dz = rzab * gab
142
143			px(a) = px(a) + rma * dx
144			py(a) = py(a) + rma * dy
145			pz(a) = pz(a) + rma * dz
146
147			px(b) = px(b) - rmb * dx
148			py(b) = py(b) - rmb * dy
149			pz(b) = pz(b) - rmb * dz
150
151			dx = dx / dt
152			dy = dy / dt
153			dz = dz / dt
154
155			vx(a) = vx(a) + rma * dx
156			vy(a) = vy(a) + rma * dy
157			vz(a) = vz(a) + rma * dz
158
159			vx(b) = vx(b) - rmb * dx
160			vy(b) = vy(b) - rmb * dy
161			vz(b) = vz(b) - rmb * dz
162
163			moving(a) = .true.
164			moving(b) = .true.
165			done = .false.
166
167			endif
168			endif
169
170			enddo
171
172			do i = 1, natoms
173			moved(i) = moving(i)
174			moving(i) = .false.
175			enddo
176
177			it = it + 1
178			enddo
179
180			c end of iterative loop
181
182			if( .not. done) then
183			write (*, '('' too many constraint iterations in move_a '')' )
184			stop
185			endif
186
187			c store new values
188
189			do i = 1, natoms
190			rx(i) = px(i)
191			ry(i) = py(i)
192			rz(i) = pz(i)
193			enddo
194
195
196
197			RETURN
198			end subroutine v_constrain_a
199
200
201
202			Subroutine v_constrain_b(dt,natoms,mass,rx,ry,rz,
203			+ vx,vy,vz,fx,fy,fz,k, n_constrained, constraints_sqr,
204			+ c_i, c_j, box_x, box_y, box_z)
205			implicit none
206
207			c ! *******************************************************************
208			c ! SECOND PART OF VELOCITY VERLET ALGORITHM
209			c !
210			c ! USAGE:
211			c !
212			c ! THE SECOND PART OF THE ALGORITHM ADVANCES VELOCITIES FROM
213			c ! T + DT/2 TO T + DT. THIS ASSUMES THAT FORCES HAVE BEEN
214			c ! COMPUTED IN THE FORCE ROUTINE AND STORED IN FX, FY, FZ.
215			c ! *******************************************************************
216
217			c ! declarations
218
219			integer i
220			double precision accvel2, dt2
221			double precision box_x, box_y, box_z
222
223			c !Global Parameters
224
225
226			INTEGER natoms
227
228			c !Global arrays
229
230			double precision mass(natoms)
231			double precision RX(natoms), RY(natoms), RZ(natoms) !position
232			double precision VX(natoms), VY(natoms), VZ(natoms) !velocity
233			double precision FX(natoms), FY(natoms), FZ(natoms) !force
234
235
236			c ! Declaration for the kinetic energy
237
238			double precision k
239
240			c ! Paramaters for force subroutines
241
242			double precision dt
243
244			c constraint parameters and variables
245
246			double precision tol, rxab, ryab, rzab, gab
247
248			double precision vxab, vyab, vzab, dx, dy, dz, rma, rmb, rvab
249			integer a, b, it, maxit, n_constrained
250			parameter ( maxit = 100 )
251			logical done
252			logical moving(natoms), moved(natoms)
253			integer c_i(n_constrained), c_j(n_constrained)
254			double precision constraints_sqr(n_constrained)
255
256			double precision e_convert
257			parameter ( e_convert = 4.184d-4 )
258
259
260			c ! *******************************************************************
261
262			tol = 1.0d-6 / dt
263			dt2 = dt / 2.0d0
264			accvel2 = 0.0d0
265			k = 0.0d0
266			DO i = 1, natoms
267
268			VX(I) = VX(I) + (DT2 * FX(I) * e_convert / mass(i))
269			VY(I) = VY(I) + (DT2 * FY(I) * e_convert / mass(i))
270			VZ(I) = VZ(I) + (DT2 * FZ(I) * e_convert / mass(i))
271
272			moving(i) = .false.
273			moved(i) = .true.
274			enddo
275
276			it = 0
277			done = .false.
278
279			do while( (.not. done) .and. ( it .le. maxit) )
280
281			done = .true.
282
283			do i=1, n_constrained
284
285			a = c_i(i)
286			b = c_j(i)
287
288			if( moved(a) .or. moved(b) ) then
289
290			vxab = vx(a) - vx(b)
291			vyab = vy(a) - vy(b)
292			vzab = vz(a) - vz(b)
293
294			rxab = rx(a) - rx(b)
295			ryab = ry(a) - ry(b)
296			rzab = rz(a) - rz(b)
297
298			rxab = rxab - box_x * dsign( 1.0d0, rxab )
299			+ * int( dabs( rxab / box_x ) + 0.5d0 )
300			ryab = ryab - box_y * dsign( 1.0d0, ryab )
301			+ * int( dabs( ryab / box_y ) + 0.5d0 )
302			rzab = rzab - box_z * dsign( 1.0d0, rzab )
303			+ * int( dabs( rzab / box_z ) + 0.5d0 )
304
305
306			rma = 1.0d0 / mass(a)
307			rmb = 1.0d0 / mass(b)
308
309			rvab = rxab * vxab + ryab * vyab + rzab * vzab
310
311			gab = -rvab / ( ( rma + rmb ) * constraints_sqr(i) )
312
313			if ( dabs(gab) .gt. tol) then
314
315			dx = rxab * gab
316			dy = ryab * gab
317			dz = rzab * gab
318
319			vx(a) = vx(a) + rma * dx
320			vy(a) = vy(a) + rma * dy
321			vz(a) = vz(a) + rma * dz
322
323			vx(b) = vx(b) - rmb * dx
324			vy(b) = vy(b) - rmb * dy
325			vz(b) = vz(b) - rmb * dz
326
327			moving(a) = .true.
328			moving(b) = .true.
329			done = .false.
330
331			endif
332
333			endif
334
335			enddo
336
337			do i = 1, natoms
338
339			moved(i) = moving(i)
340			moving(i) = .false.
341
342			enddo
343
344			it = it + 1
345
346			enddo
347
348			c End of iterative loop
349
350			if (.not. done) then
351
352			write(*, '('' Too many constraint iterations in moveb '')')
353			stop
354
355			endif
356
357			do i = 1, natoms
358
359			accvel2 = VX(I) 2 + VY(I) 2 + VZ(I) ** 2
360			k = k + 0.5d0 * mass(i) * accvel2 / e_convert
361
362			end do
363
364
365			end subroutine v_constrain_b