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source: palm/trunk/SOURCE/data_output_ptseries.f90 @ 72

Last change on this file since 72 was 60, checked in by raasch, 17 years ago
preliminary update of further changes, running
Property svn:keywords set to `Id`
File size: 10.8 KB

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1	SUBROUTINE data_output_ptseries
2
3	!------------------------------------------------------------------------------!
4	! Actual revisions:
5	! -----------------
6	! Particles-package is now part of the default code.
7	!
8	! Former revisions:
9	! -----------------
10	! $Id: data_output_ptseries.f90 60 2007-03-11 11:50:04Z raasch $
11	! RCS Log replace by Id keyword, revision history cleaned up
12	!
13	! Revision 1.2 2006/08/22 13:51:13 raasch
14	! Seperate output for particle groups
15	!
16	! Revision 1.1 2006/08/04 14:24:18 raasch
17	! Initial revision
18	!
19	!
20	! Description:
21	! ------------
22	! Output of particle data timeseries in NetCDF format.
23	!------------------------------------------------------------------------------!
24
25	USE control_parameters
26	USE cpulog
27	USE indices
28	USE interfaces
29	USE netcdf_control
30	USE particle_attributes
31	USE pegrid
32
33	IMPLICIT NONE
34
35
36	INTEGER :: i, inum, j, n
37
38	REAL, DIMENSION(0:number_of_particle_groups,30) :: pts_value, pts_value_l
39
40
41
42	CALL cpu_log( log_point(36), 'data_output_ptseries', 'start' )
43
44	IF ( myid == 0 .AND. netcdf_output ) THEN
45	!
46	!-- Open file for time series output in NetCDF format
47	dopts_time_count = dopts_time_count + 1
48	CALL check_open( 109 )
49	#if defined( __netcdf )
50	!
51	!-- Update the particle time series time axis
52	nc_stat = NF90_PUT_VAR( id_set_pts, id_var_time_pts, &
53	(/ simulated_time /), &
54	start = (/ dopts_time_count /), count = (/ 1 /) )
55	IF (nc_stat /= NF90_NOERR) CALL handle_netcdf_error( 391 )
56	#endif
57
58	ENDIF
59
60	pts_value_l = 0.0
61
62	!
63	!-- Calculate or collect the particle time series quantities for all particles
64	!-- and seperately for each particle group (if there is more than one group)
65	DO n = 1, number_of_particles
66
67	pts_value_l(0,1) = number_of_particles ! total # of particles
68	pts_value_l(0,2) = pts_value_l(0,2) + &
69	( particles(n)%x - particles(n)%origin_x ) ! mean x
70	pts_value_l(0,3) = pts_value_l(0,3) + &
71	( particles(n)%y - particles(n)%origin_y ) ! mean y
72	pts_value_l(0,4) = pts_value_l(0,4) + &
73	( particles(n)%z - particles(n)%origin_z ) ! mean z
74	pts_value_l(0,5) = pts_value_l(0,5) + particles(n)%z ! mean z (absolute)
75	pts_value_l(0,6) = pts_value_l(0,6) + particles(n)%speed_x ! mean u
76	pts_value_l(0,7) = pts_value_l(0,7) + particles(n)%speed_y ! mean v
77	pts_value_l(0,8) = pts_value_l(0,8) + particles(n)%speed_z ! mean w
78	pts_value_l(0,9) = pts_value_l(0,9) + &
79	particles(n)%speed_x_sgs ! mean sgsu
80	pts_value_l(0,10) = pts_value_l(0,10) + &
81	particles(n)%speed_y_sgs ! mean sgsv
82	pts_value_l(0,11) = pts_value_l(0,11) + &
83	particles(n)%speed_z_sgs ! mean sgsw
84	IF ( particles(n)%speed_z > 0.0 ) THEN
85	pts_value_l(0,12) = pts_value_l(0,12) + 1.0 ! # of upward moving prts
86	pts_value_l(0,13) = pts_value_l(0,13) + &
87	particles(n)%speed_z ! mean w upw.
88	ELSE
89	pts_value_l(0,14) = pts_value_l(0,14) + &
90	particles(n)%speed_z ! mean w down
91	ENDIF
92	pts_value_l(0,15) = number_of_particles
93	pts_value_l(0,16) = number_of_particles
94
95	!
96	!-- Repeat the same for the respective particle group
97	IF ( number_of_particle_groups > 1 ) THEN
98	j = particles(n)%group
99
100	pts_value_l(j,1) = pts_value_l(j,1) + 1
101	pts_value_l(j,2) = pts_value_l(j,2) + &
102	( particles(n)%x - particles(n)%origin_x )
103	pts_value_l(j,3) = pts_value_l(j,3) + &
104	( particles(n)%y - particles(n)%origin_y )
105	pts_value_l(j,4) = pts_value_l(j,4) + &
106	( particles(n)%z - particles(n)%origin_z )
107	pts_value_l(j,5) = pts_value_l(j,5) + particles(n)%z
108	pts_value_l(j,6) = pts_value_l(j,6) + particles(n)%speed_x
109	pts_value_l(j,7) = pts_value_l(j,7) + particles(n)%speed_y
110	pts_value_l(j,8) = pts_value_l(j,8) + particles(n)%speed_z
111	pts_value_l(j,9) = pts_value_l(j,9) + particles(n)%speed_x_sgs
112	pts_value_l(j,10) = pts_value_l(j,10) + particles(n)%speed_y_sgs
113	pts_value_l(j,11) = pts_value_l(j,11) + particles(n)%speed_z_sgs
114	IF ( particles(n)%speed_z > 0.0 ) THEN
115	pts_value_l(j,12) = pts_value_l(j,12) + 1.0
116	pts_value_l(j,13) = pts_value_l(j,13) + particles(n)%speed_z
117	ELSE
118	pts_value_l(j,14) = pts_value_l(j,14) + particles(n)%speed_z
119	ENDIF
120	pts_value_l(j,15) = pts_value_l(j,15) + 1.0
121	pts_value_l(j,16) = pts_value_l(j,16) + 1.0
122
123	ENDIF
124
125	ENDDO
126
127	#if defined( __parallel )
128	!
129	!-- Sum values of the subdomains
130	inum = number_of_particle_groups + 1
131
132	CALL MPI_ALLREDUCE( pts_value_l(0,1), pts_value(0,1), 14*inum, MPI_REAL, &
133	MPI_SUM, comm2d, ierr )
134	CALL MPI_ALLREDUCE( pts_value_l(0,15), pts_value(0,15), inum, MPI_REAL, &
135	MPI_MAX, comm2d, ierr )
136	CALL MPI_ALLREDUCE( pts_value_l(0,16), pts_value(0,16), inum, MPI_REAL, &
137	MPI_MIN, comm2d, ierr )
138	#else
139	pts_value(:,1:16) = pts_value_l(:,1:16)
140	#endif
141
142	!
143	!-- Normalize the above calculated quantities with the total number of
144	!-- particles
145	IF ( number_of_particle_groups > 1 ) THEN
146	inum = number_of_particle_groups
147	ELSE
148	inum = 0
149	ENDIF
150
151	DO j = 0, inum
152
153	IF ( pts_value(j,1) > 0.0 ) THEN
154
155	pts_value(j,2:14) = pts_value(j,2:14) / pts_value(j,1)
156	IF ( pts_value(j,12) > 0.0 .AND. pts_value(j,12) < 1.0 ) THEN
157	pts_value(j,13) = pts_value(j,13) / pts_value(j,12)
158	pts_value(j,14) = pts_value(j,14) / ( 1.0 - pts_value(j,12) )
159	ELSEIF ( pts_value(j,12) == 0.0 ) THEN
160	pts_value(j,13) = -1.0
161	ELSE
162	pts_value(j,14) = -1.0
163	ENDIF
164
165	ENDIF
166
167	ENDDO
168
169	!
170	!-- Calculate higher order moments of particle time series quantities,
171	!-- seperately for each particle group (if there is more than one group)
172	DO n = 1, number_of_particles
173
174	pts_value_l(0,17) = pts_value_l(0,17) + ( particles(n)%x - &
175	particles(n)%origin_x - pts_value(0,2) )*2 ! x2
176	pts_value_l(0,18) = pts_value_l(0,18) + ( particles(n)%y - &
177	particles(n)%origin_y - pts_value(0,3) )*2 ! y2
178	pts_value_l(0,19) = pts_value_l(0,19) + ( particles(n)%z - &
179	particles(n)%origin_z - pts_value(0,4) )*2 ! z2
180	pts_value_l(0,20) = pts_value_l(0,20) + ( particles(n)%speed_x - &
181	pts_value(0,6) )*2 ! u2
182	pts_value_l(0,21) = pts_value_l(0,21) + ( particles(n)%speed_y - &
183	pts_value(0,7) )*2 ! v2
184	pts_value_l(0,22) = pts_value_l(0,22) + ( particles(n)%speed_z - &
185	pts_value(0,8) )*2 ! w2
186	pts_value_l(0,23) = pts_value_l(0,23) + ( particles(n)%speed_x_sgs - &
187	pts_value(0,9) )**2 ! u"2
188	pts_value_l(0,24) = pts_value_l(0,24) + ( particles(n)%speed_y_sgs - &
189	pts_value(0,10) )**2 ! v"2
190	pts_value_l(0,25) = pts_value_l(0,25) + ( particles(n)%speed_z_sgs - &
191	pts_value(0,11) )**2 ! w"2
192	!
193	!-- Repeat the same for the respective particle group
194	IF ( number_of_particle_groups > 1 ) THEN
195	j = particles(n)%group
196
197	pts_value_l(j,17) = pts_value_l(j,17) + ( particles(n)%x - &
198	particles(n)%origin_x - pts_value(j,2) )**2
199	pts_value_l(j,18) = pts_value_l(j,18) + ( particles(n)%y - &
200	particles(n)%origin_y - pts_value(j,3) )**2
201	pts_value_l(j,19) = pts_value_l(j,19) + ( particles(n)%z - &
202	particles(n)%origin_z - pts_value(j,4) )**2
203	pts_value_l(j,20) = pts_value_l(j,20) + ( particles(n)%speed_x - &
204	pts_value(j,6) )**2
205	pts_value_l(j,21) = pts_value_l(j,21) + ( particles(n)%speed_y - &
206	pts_value(j,7) )**2
207	pts_value_l(j,22) = pts_value_l(j,22) + ( particles(n)%speed_z - &
208	pts_value(j,8) )**2
209	pts_value_l(j,23) = pts_value_l(j,23) + ( particles(n)%speed_x_sgs - &
210	pts_value(j,9) )**2
211	pts_value_l(j,24) = pts_value_l(j,24) + ( particles(n)%speed_y_sgs - &
212	pts_value(j,10) )**2
213	pts_value_l(j,25) = pts_value_l(j,25) + ( particles(n)%speed_z_sgs - &
214	pts_value(j,11) )**2
215	ENDIF
216
217	ENDDO
218
219	pts_value_l(0,26) = ( number_of_particles - pts_value(0,1) / numprocs )**2
220	! variance of particle numbers
221	IF ( number_of_particle_groups > 1 ) THEN
222	DO j = 1, number_of_particle_groups
223	pts_value_l(j,26) = ( pts_value_l(j,1) - &
224	pts_value(j,1) / numprocs )**2
225	ENDDO
226	ENDIF
227
228	#if defined( __parallel )
229	!
230	!-- Sum values of the subdomains
231	inum = number_of_particle_groups + 1
232
233	CALL MPI_ALLREDUCE( pts_value_l(0,17), pts_value(0,17), inum*10, MPI_REAL, &
234	MPI_SUM, comm2d, ierr )
235	#else
236	pts_value(:,17:26) = pts_value_l(:,17:26)
237	#endif
238
239	!
240	!-- Normalize the above calculated quantities with the total number of
241	!-- particles
242	IF ( number_of_particle_groups > 1 ) THEN
243	inum = number_of_particle_groups
244	ELSE
245	inum = 0
246	ENDIF
247
248	DO j = 0, inum
249
250	IF ( pts_value(j,1) > 0.0 ) THEN
251	pts_value(j,17:25) = pts_value(j,17:25) / pts_value(j,1)
252	ENDIF
253	pts_value(j,26) = pts_value(j,26) / numprocs
254
255	ENDDO
256
257	#if defined( __netcdf )
258	!
259	!-- Output particle time series quantities in NetCDF format
260	IF ( myid == 0 .AND. netcdf_output ) THEN
261	DO j = 0, inum
262	DO i = 1, dopts_num
263	nc_stat = NF90_PUT_VAR( id_set_pts, id_var_dopts(i,j), &
264	(/ pts_value(j,i) /), &
265	start = (/ dopts_time_count /), &
266	count = (/ 1 /) )
267	IF ( nc_stat /= NF90_NOERR ) CALL handle_netcdf_error( 392 )
268	ENDDO
269	ENDDO
270	ENDIF
271	#endif
272
273	CALL cpu_log( log_point(36), 'data_output_ptseries','stop', 'nobarrier' )
274
275	END SUBROUTINE data_output_ptseries

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