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source: palm/trunk/SOURCE/diffusion_v.f90 @ 53

Last change on this file since 53 was 53, checked in by raasch, 17 years ago
preliminary version, several changes to be explained later
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Rev	Line
[1]	1	MODULE diffusion_v_mod
	2
	3	!------------------------------------------------------------------------------!
	4	! Actual revisions:
	5	! -----------------
[53]	6	! Wall functions now include diabatic conditions, call of routine wall_fluxes
[1]	7	!
	8	! Former revisions:
	9	! -----------------
[3]	10	! $Id: diffusion_v.f90 53 2007-03-07 12:33:47Z raasch $
[39]	11	!
	12	! 20 2007-02-26 00:12:32Z raasch
	13	! Bugfix: ddzw dimensioned 1:nzt"+1"
	14	!
[3]	15	! RCS Log replace by Id keyword, revision history cleaned up
	16	!
[1]	17	! Revision 1.15 2006/02/23 10:36:00 raasch
	18	! nzb_2d replaced by nzb_v_outer in horizontal diffusion and by nzb_v_inner
	19	! or nzb_diff_v, respectively, in vertical diffusion,
	20	! wall functions added for north and south walls, +z0 in argument list,
	21	! terms containing w(k-1,..) are removed from the Prandtl-layer equation
	22	! because they cause errors at the edges of topography
	23	! WARNING: loops containing the MAX function are still not properly vectorized!
	24	!
	25	! Revision 1.1 1997/09/12 06:24:01 raasch
	26	! Initial revision
	27	!
	28	!
	29	! Description:
	30	! ------------
	31	! Diffusion term of the v-component
	32	!------------------------------------------------------------------------------!
	33
	34	PRIVATE
	35	PUBLIC diffusion_v
	36
	37	INTERFACE diffusion_v
	38	MODULE PROCEDURE diffusion_v
	39	MODULE PROCEDURE diffusion_v_ij
	40	END INTERFACE diffusion_v
	41
	42	CONTAINS
	43
	44
	45	!------------------------------------------------------------------------------!
	46	! Call for all grid points
	47	!------------------------------------------------------------------------------!
	48	SUBROUTINE diffusion_v( ddzu, ddzw, km, km_damp_x, tend, u, v, vsws, w, z0 )
	49
	50	USE control_parameters
	51	USE grid_variables
	52	USE indices
	53
	54	IMPLICIT NONE
	55
	56	INTEGER :: i, j, k
[51]	57	REAL :: kmxm_x, kmxm_y, kmxp_x, kmxp_y, kmzm, kmzp
[20]	58	REAL :: ddzu(1:nzt+1), ddzw(1:nzt+1), km_damp_x(nxl-1:nxr+1)
[1]	59	REAL :: z0(nys-1:nyn+1,nxl-1:nxr+1)
	60	REAL :: tend(nzb:nzt+1,nys-1:nyn+1,nxl-1:nxr+1)
[51]	61	REAL, DIMENSION(nzb:nzt+1) :: vsus
[1]	62	REAL, DIMENSION(:,:), POINTER :: vsws
	63	REAL, DIMENSION(:,:,:), POINTER :: km, u, v, w
	64
	65	DO i = nxl, nxr
	66	DO j = nys, nyn+vynp
	67	!
	68	!-- Compute horizontal diffusion
	69	DO k = nzb_v_outer(j,i)+1, nzt
	70	!
	71	!-- Interpolate eddy diffusivities on staggered gridpoints
	72	kmxp_x = 0.25 * &
	73	( km(k,j,i)+km(k,j,i+1)+km(k,j-1,i)+km(k,j-1,i+1) )
	74	kmxm_x = 0.25 * &
	75	( km(k,j,i)+km(k,j,i-1)+km(k,j-1,i)+km(k,j-1,i-1) )
	76	kmxp_y = kmxp_x
	77	kmxm_y = kmxm_x
	78	!
	79	!-- Increase diffusion at the outflow boundary in case of
	80	!-- non-cyclic lateral boundaries. Damping is only needed for
	81	!-- velocity components parallel to the outflow boundary in
	82	!-- the direction normal to the outflow boundary.
	83	IF ( bc_lr /= 'cyclic' ) THEN
	84	kmxp_x = MAX( kmxp_x, km_damp_x(i) )
	85	kmxm_x = MAX( kmxm_x, km_damp_x(i) )
	86	ENDIF
	87
	88	tend(k,j,i) = tend(k,j,i) &
	89	& + ( kmxp_x * ( v(k,j,i+1) - v(k,j,i) ) * ddx &
	90	& + kmxp_y * ( u(k,j,i+1) - u(k,j-1,i+1) ) * ddy &
	91	& - kmxm_x * ( v(k,j,i) - v(k,j,i-1) ) * ddx &
	92	& - kmxm_y * ( u(k,j,i) - u(k,j-1,i) ) * ddy &
	93	& ) * ddx &
	94	& + 2.0 * ( &
	95	& km(k,j,i) * ( v(k,j+1,i) - v(k,j,i) ) &
	96	& - km(k,j-1,i) * ( v(k,j,i) - v(k,j-1,i) ) &
	97	& ) * ddy2
	98	ENDDO
	99
	100	!
	101	!-- Wall functions at the left and right walls, respectively
	102	IF ( wall_v(j,i) /= 0.0 ) THEN
[51]	103
	104	!
	105	!-- Calculate the horizontal momentum flux v'u'
	106	CALL wall_fluxes( i, j, nzb_v_inner(j,i)+1, nzb_v_outer(j,i), &
	107	vsus, 0.0, 1.0, 0.0, 0.0 )
	108
[1]	109	DO k = nzb_v_inner(j,i)+1, nzb_v_outer(j,i)
	110	kmxp_x = 0.25 * &
	111	( km(k,j,i)+km(k,j,i+1)+km(k,j-1,i)+km(k,j-1,i+1) )
	112	kmxm_x = 0.25 * &
	113	( km(k,j,i)+km(k,j,i-1)+km(k,j-1,i)+km(k,j-1,i-1) )
	114	kmxp_y = kmxp_x
	115	kmxm_y = kmxm_x
	116	!
	117	!-- Increase diffusion at the outflow boundary in case of
	118	!-- non-cyclic lateral boundaries. Damping is only needed for
	119	!-- velocity components parallel to the outflow boundary in
	120	!-- the direction normal to the outflow boundary.
	121	IF ( bc_lr /= 'cyclic' ) THEN
	122	kmxp_x = MAX( kmxp_x, km_damp_x(i) )
	123	kmxm_x = MAX( kmxm_x, km_damp_x(i) )
	124	ENDIF
	125
	126	tend(k,j,i) = tend(k,j,i) &
	127	+ 2.0 * ( &
	128	km(k,j,i) * ( v(k,j+1,i) - v(k,j,i) ) &
	129	- km(k,j-1,i) * ( v(k,j,i) - v(k,j-1,i) ) &
	130	) * ddy2 &
	131	+ ( fxp(j,i) * ( &
	132	kmxp_x * ( v(k,j,i+1) - v(k,j,i) ) * ddx &
	133	+ kmxp_y * ( u(k,j,i+1) - u(k,j-1,i+1) ) * ddy &
	134	) &
	135	- fxm(j,i) * ( &
	136	kmxm_x * ( v(k,j,i) - v(k,j,i-1) ) * ddx &
	137	+ kmxm_y * ( u(k,j,i) - u(k,j-1,i) ) * ddy &
	138	) &
[51]	139	+ wall_v(j,i) * vsus(k) &
[1]	140	) * ddx
	141	ENDDO
	142	ENDIF
	143
	144	!
	145	!-- Compute vertical diffusion. In case of simulating a Prandtl
	146	!-- layer, index k starts at nzb_v_inner+2.
	147	DO k = nzb_diff_v(j,i), nzt
	148	!
	149	!-- Interpolate eddy diffusivities on staggered gridpoints
	150	kmzp = 0.25 * &
	151	( km(k,j,i)+km(k+1,j,i)+km(k,j-1,i)+km(k+1,j-1,i) )
	152	kmzm = 0.25 * &
	153	( km(k,j,i)+km(k-1,j,i)+km(k,j-1,i)+km(k-1,j-1,i) )
	154
	155	tend(k,j,i) = tend(k,j,i) &
	156	& + ( kmzp * ( ( v(k+1,j,i) - v(k,j,i) ) * ddzu(k+1) &
	157	& + ( w(k,j,i) - w(k,j-1,i) ) * ddy &
	158	& ) &
	159	& - kmzm * ( ( v(k,j,i) - v(k-1,j,i) ) * ddzu(k) &
	160	& + ( w(k-1,j,i) - w(k-1,j-1,i) ) * ddy &
	161	& ) &
	162	& ) * ddzw(k)
	163	ENDDO
	164
	165	!
	166	!-- Vertical diffusion at the first grid point above the surface,
	167	!-- if the momentum flux at the bottom is given by the Prandtl law
	168	!-- or if it is prescribed by the user.
	169	!-- Difference quotient of the momentum flux is not formed over
	170	!-- half of the grid spacing (2.0*ddzw(k)) any more, since the
	171	!-- comparison with other (LES) modell showed that the values of
	172	!-- the momentum flux becomes too large in this case.
	173	!-- The term containing w(k-1,..) (see above equation) is removed here
	174	!-- because the vertical velocity is assumed to be zero at the surface.
	175	IF ( use_surface_fluxes ) THEN
	176	k = nzb_v_inner(j,i)+1
	177	!
	178	!-- Interpolate eddy diffusivities on staggered gridpoints
	179	kmzp = 0.25 * &
	180	( km(k,j,i)+km(k+1,j,i)+km(k,j-1,i)+km(k+1,j-1,i) )
	181	kmzm = 0.25 * &
	182	( km(k,j,i)+km(k-1,j,i)+km(k,j-1,i)+km(k-1,j-1,i) )
	183
	184	tend(k,j,i) = tend(k,j,i) &
	185	& + ( kmzp * ( w(k,j,i) - w(k,j-1,i) ) * ddy &
	186	& ) * ddzw(k) &
	187	& + ( kmzp * ( v(k+1,j,i) - v(k,j,i) ) * ddzu(k+1) &
	188	& + vsws(j,i) &
	189	& ) * ddzw(k)
	190	ENDIF
	191
	192	ENDDO
	193	ENDDO
	194
	195	END SUBROUTINE diffusion_v
	196
	197
	198	!------------------------------------------------------------------------------!
	199	! Call for grid point i,j
	200	!------------------------------------------------------------------------------!
	201	SUBROUTINE diffusion_v_ij( i, j, ddzu, ddzw, km, km_damp_x, tend, u, v, &
	202	vsws, w, z0 )
	203
	204	USE control_parameters
	205	USE grid_variables
	206	USE indices
	207
	208	IMPLICIT NONE
	209
	210	INTEGER :: i, j, k
[51]	211	REAL :: kmxm_x, kmxm_y, kmxp_x, kmxp_y, kmzm, kmzp
[20]	212	REAL :: ddzu(1:nzt+1), ddzw(1:nzt+1), km_damp_x(nxl-1:nxr+1)
[1]	213	REAL :: z0(nys-1:nyn+1,nxl-1:nxr+1)
	214	REAL :: tend(nzb:nzt+1,nys-1:nyn+1,nxl-1:nxr+1)
[51]	215	REAL, DIMENSION(nzb:nzt+1) :: vsus
[1]	216	REAL, DIMENSION(:,:), POINTER :: vsws
	217	REAL, DIMENSION(:,:,:), POINTER :: km, u, v, w
	218
	219	!
	220	!-- Compute horizontal diffusion
	221	DO k = nzb_v_outer(j,i)+1, nzt
	222	!
	223	!-- Interpolate eddy diffusivities on staggered gridpoints
	224	kmxp_x = 0.25 * ( km(k,j,i)+km(k,j,i+1)+km(k,j-1,i)+km(k,j-1,i+1) )
	225	kmxm_x = 0.25 * ( km(k,j,i)+km(k,j,i-1)+km(k,j-1,i)+km(k,j-1,i-1) )
	226	kmxp_y = kmxp_x
	227	kmxm_y = kmxm_x
	228	!
	229	!-- Increase diffusion at the outflow boundary in case of non-cyclic
	230	!-- lateral boundaries. Damping is only needed for velocity components
	231	!-- parallel to the outflow boundary in the direction normal to the
	232	!-- outflow boundary.
	233	IF ( bc_lr /= 'cyclic' ) THEN
	234	kmxp_x = MAX( kmxp_x, km_damp_x(i) )
	235	kmxm_x = MAX( kmxm_x, km_damp_x(i) )
	236	ENDIF
	237
	238	tend(k,j,i) = tend(k,j,i) &
	239	& + ( kmxp_x * ( v(k,j,i+1) - v(k,j,i) ) * ddx &
	240	& + kmxp_y * ( u(k,j,i+1) - u(k,j-1,i+1) ) * ddy &
	241	& - kmxm_x * ( v(k,j,i) - v(k,j,i-1) ) * ddx &
	242	& - kmxm_y * ( u(k,j,i) - u(k,j-1,i) ) * ddy &
	243	& ) * ddx &
	244	& + 2.0 * ( &
	245	& km(k,j,i) * ( v(k,j+1,i) - v(k,j,i) ) &
	246	& - km(k,j-1,i) * ( v(k,j,i) - v(k,j-1,i) ) &
	247	& ) * ddy2
	248	ENDDO
	249
	250	!
	251	!-- Wall functions at the left and right walls, respectively
	252	IF ( wall_v(j,i) /= 0.0 ) THEN
[51]	253
	254	!
	255	!-- Calculate the horizontal momentum flux v'u'
	256	CALL wall_fluxes( i, j, nzb_v_inner(j,i)+1, nzb_v_outer(j,i), &
	257	vsus, 0.0, 1.0, 0.0, 0.0 )
	258
[1]	259	DO k = nzb_v_inner(j,i)+1, nzb_v_outer(j,i)
	260	kmxp_x = 0.25 * &
	261	( km(k,j,i)+km(k,j,i+1)+km(k,j-1,i)+km(k,j-1,i+1) )
	262	kmxm_x = 0.25 * &
	263	( km(k,j,i)+km(k,j,i-1)+km(k,j-1,i)+km(k,j-1,i-1) )
	264	kmxp_y = kmxp_x
	265	kmxm_y = kmxm_x
	266	!
	267	!-- Increase diffusion at the outflow boundary in case of
	268	!-- non-cyclic lateral boundaries. Damping is only needed for
	269	!-- velocity components parallel to the outflow boundary in
	270	!-- the direction normal to the outflow boundary.
	271	IF ( bc_lr /= 'cyclic' ) THEN
	272	kmxp_x = MAX( kmxp_x, km_damp_x(i) )
	273	kmxm_x = MAX( kmxm_x, km_damp_x(i) )
	274	ENDIF
	275
	276	tend(k,j,i) = tend(k,j,i) &
	277	+ 2.0 * ( &
	278	km(k,j,i) * ( v(k,j+1,i) - v(k,j,i) ) &
	279	- km(k,j-1,i) * ( v(k,j,i) - v(k,j-1,i) ) &
	280	) * ddy2 &
	281	+ ( fxp(j,i) * ( &
	282	kmxp_x * ( v(k,j,i+1) - v(k,j,i) ) * ddx &
	283	+ kmxp_y * ( u(k,j,i+1) - u(k,j-1,i+1) ) * ddy &
	284	) &
	285	- fxm(j,i) * ( &
	286	kmxm_x * ( v(k,j,i) - v(k,j,i-1) ) * ddx &
	287	+ kmxm_y * ( u(k,j,i) - u(k,j-1,i) ) * ddy &
	288	) &
[51]	289	+ wall_v(j,i) * vsus(k) &
[1]	290	) * ddx
	291	ENDDO
	292	ENDIF
	293
	294	!
	295	!-- Compute vertical diffusion. In case of simulating a Prandtl layer,
	296	!-- index k starts at nzb_v_inner+2.
	297	DO k = nzb_diff_v(j,i), nzt
	298	!
	299	!-- Interpolate eddy diffusivities on staggered gridpoints
	300	kmzp = 0.25 * ( km(k,j,i)+km(k+1,j,i)+km(k,j-1,i)+km(k+1,j-1,i) )
	301	kmzm = 0.25 * ( km(k,j,i)+km(k-1,j,i)+km(k,j-1,i)+km(k-1,j-1,i) )
	302
	303	tend(k,j,i) = tend(k,j,i) &
	304	& + ( kmzp * ( ( v(k+1,j,i) - v(k,j,i) ) * ddzu(k+1) &
	305	& + ( w(k,j,i) - w(k,j-1,i) ) * ddy &
	306	& ) &
	307	& - kmzm * ( ( v(k,j,i) - v(k-1,j,i) ) * ddzu(k) &
	308	& + ( w(k-1,j,i) - w(k-1,j-1,i) ) * ddy &
	309	& ) &
	310	& ) * ddzw(k)
	311	ENDDO
	312
	313	!
	314	!-- Vertical diffusion at the first grid point above the surface, if the
	315	!-- momentum flux at the bottom is given by the Prandtl law or if it is
	316	!-- prescribed by the user.
	317	!-- Difference quotient of the momentum flux is not formed over half of
	318	!-- the grid spacing (2.0*ddzw(k)) any more, since the comparison with
	319	!-- other (LES) modell showed that the values of the momentum flux becomes
	320	!-- too large in this case.
	321	!-- The term containing w(k-1,..) (see above equation) is removed here
	322	!-- because the vertical velocity is assumed to be zero at the surface.
	323	IF ( use_surface_fluxes ) THEN
	324	k = nzb_v_inner(j,i)+1
	325	!
	326	!-- Interpolate eddy diffusivities on staggered gridpoints
	327	kmzp = 0.25 * ( km(k,j,i)+km(k+1,j,i)+km(k,j-1,i)+km(k+1,j-1,i) )
	328	kmzm = 0.25 * ( km(k,j,i)+km(k-1,j,i)+km(k,j-1,i)+km(k-1,j-1,i) )
	329
	330	tend(k,j,i) = tend(k,j,i) &
	331	& + ( kmzp * ( w(k,j,i) - w(k,j-1,i) ) * ddy &
	332	& ) * ddzw(k) &
	333	& + ( kmzp * ( v(k+1,j,i) - v(k,j,i) ) * ddzu(k+1) &
	334	& + vsws(j,i) &
	335	& ) * ddzw(k)
	336	ENDIF
	337
	338	END SUBROUTINE diffusion_v_ij
	339
	340	END MODULE diffusion_v_mod

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