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kpp_sdirk4.f

Last change on this file was 2696, checked in by kanani, 6 years ago
Merge of branch palm4u into trunk
File size: 19.3 KB

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1	SUBROUTINE INTEGRATE( TIN, TOUT )
2
3	IMPLICIT KPP_REAL (A-H,O-Z)
4	INCLUDE 'KPP_ROOT_Parameters.h'
5	INCLUDE 'KPP_ROOT_Global.h'
6
7	C TIN - Start Time
8	KPP_REAL TIN
9	C TOUT - End Time
10	KPP_REAL TOUT
11	INTEGER i
12
13	PARAMETER (LWORK=2NVARNVAR+12NVAR+7,LIWORK=2NVAR+7)
14	PARAMETER (LRCONT=5*NVAR+2)
15
16	KPP_REAL WORK(LWORK)
17	INTEGER IWORK(LIWORK)
18	COMMON /CONT/ ICONT(4),RCONT(LRCONT)
19	EXTERNAL FUNC_CHEM,JAC_CHEM
20
21	ITOL=1 ! --- VECTOR TOLERANCES
22	IJAC=1 ! --- COMPUTE THE JACOBIAN ANALYTICALLY
23	IMAS=0 ! --- DIFFERENTIAL EQUATION IS IN EXPLICIT FORM
24
25	DO i=1,20
26	IWORK(i) = 0
27	WORK(i) = 0.D0
28	ENDDO
29
30	IWORK(3) = 8
31
32	CALL ATMSDIRK(NVAR,FUNC_CHEM,TIN,VAR,TOUT,STEPMIN,
33	& RTOL,ATOL,ITOL,
34	& JAC_CHEM ,IJAC, FUNC_CHEM ,IMAS,
35	& WORK,LWORK,IWORK,LIWORK,LRCONT,IDID)
36
37	IF (IDID.LT.0) THEN
38	print *,'ATMSDIRK: Unsucessfull exit at T=',
39	& TIN,' (IDID=',IDID,')'
40	ENDIF
41
42	RETURN
43	END
44
45
46	SUBROUTINE ATMSDIRK(N,FCN,X,Y,XEND,H,
47	& RelTol,AbsTol,ITOL,
48	& JAC ,IJAC, MAS ,IMAS,
49	& WORK,LWORK,IWORK,LIWORK,LRCONT,IDID)
50	C ----------------------------------------------------------
51	C * * * * * * * * * * * * ***
52	C DECLARATIONS
53	C * * * * * * * * * * * * ***
54	IMPLICIT KPP_REAL (A-H,O-Z)
55	DIMENSION Y(N),AbsTol(1),RelTol(1),WORK(LWORK),IWORK(LIWORK)
56	LOGICAL IMPLCT,JBAND,ARRET
57	EXTERNAL FCN,JAC,MAS
58	COMMON/STAT/NFCN,NJAC,NSTEP,NACCPT,NREJCT,NDEC,NSOL
59
60	C * * * * * * ***
61	C SETTING THE PARAMETERS
62	C * * * * * * ***
63	NFCN=0
64	NJAC=0
65	NSTEP=0
66	NACCPT=0
67	NREJCT=0
68	NDEC=0
69	NSOL=0
70	ARRET=.FALSE.
71	C -------- SWITCH FOR TRANSFORMATION OF JACOBIAN TO HESS_CHEM FORM ---
72	NHESS1 = 0 ! ADRIAN
73	C -------- NMAX , THE MAXIMAL NUMBER OF STEPS -----
74	IF(IWORK(2).EQ.0)THEN
75	NMAX=100000
76	ELSE
77	NMAX=IWORK(2)
78	IF(NMAX.LE.0)THEN
79	WRITE(6,*)' WRONG INPUT IWORK(2)=',IWORK(2)
80	ARRET=.TRUE.
81	END IF
82	END IF
83	C -------- NIT MAXIMAL NUMBER OF NEWTON ITERATIONS
84	IF(IWORK(3).EQ.0)THEN
85	NIT=8
86	ELSE
87	NIT=IWORK(3)
88	IF(NIT.LE.0)THEN
89	WRITE(6,*)' CURIOUS INPUT IWORK(3)=',IWORK(3)
90	ARRET=.TRUE.
91	END IF
92	END IF
93	C -------- METH SWITCH FOR THE COEFFICIENTS OF THE METHOD
94	METH = 2
95	C -------- UROUND SMALLEST NUMBER SATISFYING 1.D0+UROUND>1.D0
96	IF(WORK(1).EQ.0.D0)THEN
97	UROUND=1.D-16
98	ELSE
99	UROUND=WORK(1)
100	IF(UROUND.LE.1.D-19.OR.UROUND.GE.1.D0)THEN
101	WRITE(6,*)' COEFFICIENTS HAVE 20 DIGITS, UROUND=',WORK(1)
102	ARRET=.TRUE.
103	END IF
104	END IF
105	C --------- SAFE SAFETY FACTOR IN STEP SIZE PREDICTION
106	IF(WORK(2).EQ.0.D0)THEN
107	SAFE=0.9D0
108	ELSE
109	SAFE=WORK(2)
110	IF(SAFE.LE..001D0.OR.SAFE.GE.1.D0)THEN
111	WRITE(6,*)' CURIOUS INPUT FOR WORK(2)=',WORK(2)
112	ARRET=.TRUE.
113	END IF
114	END IF
115	C ------ THET DECIDES WHETHER THE JACOBIAN SHOULD BE RECOMPUTED;
116	IF(WORK(3).EQ.0.D0)THEN
117	THET=0.001D0
118	ELSE
119	THET=WORK(3)
120	END IF
121	C --- FNEWT STOPPING CRIERION FOR NEWTON'S METHOD, USUALLY CHOSEN <1.
122	IF(WORK(4).EQ.0.D0)THEN
123	FNEWT=0.03D0
124	ELSE
125	FNEWT=WORK(4)
126	END IF
127	C --- QUOT1 AND QUOT2: IF QUOT1 < HNEW/HOLD < QUOT2, STEP SIZE = CONST.
128	IF(WORK(5).EQ.0.D0)THEN
129	QUOT1=1.D0
130	ELSE
131	QUOT1=WORK(5)
132	END IF
133	IF(WORK(6).EQ.0.D0)THEN
134	QUOT2=1.2D0
135	ELSE
136	QUOT2=WORK(6)
137	END IF
138	C -------- MAXIMAL STEP SIZE
139	IF(WORK(7).EQ.0.D0)THEN
140	HMAX=XEND-X
141	ELSE
142	HMAX=WORK(7)
143	END IF
144	C --------- CHECK IF TOLERANCES ARE O.K.
145	IF (ITOL.EQ.0) THEN
146	IF (AbsTol(1).LE.0.D0.OR.RelTol(1).LE.10.D0*UROUND) THEN
147	WRITE (6,*) ' TOLERANCES ARE TOO SMALL'
148	ARRET=.TRUE.
149	END IF
150	ELSE
151	DO 15 I=1,N
152	IF (AbsTol(I).LE.0.D0.OR.RelTol(I).LE.10.D0*UROUND) THEN
153	WRITE (6,*) ' TOLERANCES(',I,') ARE TOO SMALL'
154	ARRET=.TRUE.
155	END IF
156	15 CONTINUE
157	END IF
158
159	C * * * * * * * * * * * * ***
160	C COMPUTATION OF ARRAY ENTRIES
161	C * * * * * * * * * * * * ***
162	C ---- IMPLICIT, BANDED OR NOT ?
163	IMPLCT=IMAS.NE.0
164	ARRET=.FALSE.
165	C -------- COMPUTATION OF THE ROW-DIMENSIONS OF THE 2-ARRAYS ---
166	C -- JACOBIAN
167	LDJAC=N
168	C -- MATRIX E FOR LINEAR ALGEBRA
169	LDE=N
170	C -- MASS MATRIX
171	IF (IMPLCT) THEN
172	print *,'IMPLCT 1'
173	ELSE
174	LDMAS=0
175	END IF
176	LDMAS2=MAX(1,LDMAS)
177
178	C ------- PREPARE THE ENTRY-POINTS FOR THE ARRAYS IN WORK -----
179	IEYHAT=8
180	IEZ=IEYHAT+N
181	IEY0=IEZ+N
182	IEZ1=IEY0+N
183	IEZ2=IEZ1+N
184	IEZ3=IEZ2+N
185	IEZ4=IEZ3+N
186	IEZ5=IEZ4+N
187	IESCAL=IEZ5+N
188	IEF1=IESCAL+N
189	IEG1=IEF1+N
190	IEH1=IEG1+N
191	IEJAC=IEH1+N
192	IEMAS=IEJAC+N*LDJAC
193	IEE=IEMAS+N*LDMAS
194
195	C ------ TOTAL STORAGE REQUIREMENT -----------
196	ISTORE=IEE+N*LDE-1
197	IF(ISTORE.GT.LWORK)THEN
198	WRITE(6,*)' INSUFFICIENT STORAGE FOR WORK, MIN. LWORK=',ISTORE
199	ARRET=.TRUE.
200	END IF
201	C ------- ENTRY POINTS FOR INTEGER WORKSPACE -----
202	IEIP=5
203	IEHES=IEIP+N
204	C --------- TOTAL REQUIREMENT ---------------
205	ISTORE=IEHES+N-1
206	IF(ISTORE.GT.LIWORK)THEN
207	WRITE(6,*)' INSUFF. STORAGE FOR IWORK, MIN. LIWORK=',ISTORE
208	ARRET=.TRUE.
209	END IF
210	C --------- CONTROL OF LENGTH OF COMMON BLOCK "CONT" -------
211	IF(LRCONT.LT.(5*N+2))THEN
212	WRITE(6,)' INSUFF. STORAGE FOR RCONT, MIN. LRCONT=',5N+2
213	ARRET=.TRUE.
214	END IF
215	C ------ WHEN A FAIL HAS OCCURED, WE RETURN WITH IDID=-1
216	IF (ARRET) THEN
217	IDID=-1
218	RETURN
219	END IF
220	C -------- CALL TO CORE INTEGRATOR ------------
221	CALL SDICOR(N,FCN,X,Y,XEND,HMAX,H,RelTol,AbsTol,ITOL,
222	& JAC,IJAC,MLJAC,MUJAC,MAS,MLMAS,MUMAS,IOUT,IDID,
223	& NMAX,UROUND,SAFE,THET,FNEWT,QUOT1,QUOT2,NIT,METH,NHESS1,
224	& IMPLCT,JBAND,LDJAC,LDE,LDMAS2,
225	& WORK(IEYHAT),WORK(IEZ),WORK(IEY0),WORK(IEZ1),WORK(IEZ2),
226	& WORK(IEZ3),WORK(IEZ4),WORK(IEZ5),WORK(IESCAL),WORK(IEF1),
227	& WORK(IEG1),WORK(IEH1),WORK(IEJAC),WORK(IEE),
228	& WORK(IEMAS),IWORK(IEIP),IWORK(IEHES))
229	C ----------- RETURN -----------
230	RETURN
231	END
232	C
233	C
234	C
235	C ----- ... AND HERE IS THE CORE INTEGRATOR ----------
236	C
237	SUBROUTINE SDICOR(N,FCN,X,Y,XEND,HMAX,H,RelTol,AbsTol,ITOL,
238	& JAC,IJAC,MLJAC,MUJAC,MAS,MLMAS,MUMAS,IOUT,IDID,
239	& NMAX,UROUND,SAFE,THET,FNEWT,QUOT1,QUOT2,NIT,METH,NHESS1,
240	& IMPLCT,BANDED,LDJAC,LE,LDMAS,
241	& YHAT,Z,Y0,Z1,Z2,Z3,Z4,Z5,SCAL,F1,G1,H1,FJAC,E,FMAS,IP,IPHES)
242	C ----------------------------------------------------------
243	C CORE INTEGRATOR FOR SDIRK4
244	C PARAMETERS SAME AS IN SDIRK4 WITH WORKSPACE ADDED
245	C ----------------------------------------------------------
246	C DECLARATIONS
247	C ----------------------------------------------------------
248	IMPLICIT KPP_REAL (A-H,O-Z)
249	INCLUDE 'KPP_ROOT_Parameters.h'
250	INCLUDE 'KPP_ROOT_Sparse.h'
251	KPP_REAL Y(N),YHAT(N),Z(N),Y0(N),Z1(N),Z2(N),Z3(N),Z4(N),Z5(N)
252	KPP_REAL SCAL(N),F1(N),G1(N),H1(N)
253	KPP_REAL FJAC(LU_NONZERO),E(LU_NONZERO),FMAS(LDMAS,N)
254	KPP_REAL AbsTol(1),RelTol(1)
255	INTEGER IP(N),IPHES(N)
256	LOGICAL REJECT,FIRST,IMPLCT,BANDED,CALJAC,NEWTRE
257	COMMON /CONT/NN,NN2,NN3,NN4,XOLD,HSOL,CONT(5*NVAR)
258	COMMON/STAT/NFCN,NJAC,NSTEP,NACCPT,NREJCT,NDEC,NSOL
259	EXTERNAL MAS, FCN, JAC
260
261	C * * * * * * ***
262	C INITIALISATIONS
263	C * * * * * * ***
264
265	C --------- DUPLIFY N FOR COMMON BLOCK CONT -----
266	NN=N
267	NN2=2*N
268	NN3=3*N
269	NN4=4*N
270
271	C ------- COMPUTE MASS MATRIX FOR IMPLICIT CASE ----------
272	IF(IMPLCT) CALL MAS(N,FMAS,LDMAS)
273
274	C ---------- CONSTANTS ---------
275	MBDIAG=MUMAS+1
276	IF (METH.EQ.2) THEN
277	C ---------- METHOD WITH GAMMA = 4/15 ---------------
278	GAMMA=4.0D0/15.0D0
279	C2=23.0D0/30.0D0
280	C3=17.0D0/30.0D0
281	C4=2881.0D0/28965.0D0+GAMMA
282	ALPH21=15.0D0/8.0D0
283	ALPH31=1577061.0D0/922880.0D0
284	ALPH32=-23427.0D0/115360.0D0
285	ALPH41=647163682356923881.0D0/2414496535205978880.0D0
286	ALPH42=-593512117011179.0D0/3245291041943520.0D0
287	ALPH43=559907973726451.0D0/1886325418129671.0D0
288	ALPH51=724545451.0D0/796538880.0D0
289	ALPH52=-830832077.0D0/267298560.0D0
290	ALPH53=30957577.0D0/2509272.0D0
291	ALPH54=-69863904375173.0D0/6212571137048.0D0
292	E1=7752107607.0D0/11393456128.0D0
293	E2=-17881415427.0D0/11470078208.0D0
294	E3=2433277665.0D0/179459416.0D0
295	E4=-96203066666797.0D0/6212571137048.0D0
296	D11= 24.74416644927758D0
297	D12= -4.325375951824688D0
298	D13= 41.39683763286316D0
299	D14= -61.04144619901784D0
300	D15= -3.391332232917013D0
301	D21= -51.98245719616925D0
302	D22= 10.52501981094525D0
303	D23= -154.2067922191855D0
304	D24= 214.3082125319825D0
305	D25= 14.71166018088679D0
306	D31= 33.14347947522142D0
307	D32= -19.72986789558523D0
308	D33= 230.4878502285804D0
309	D34= -287.6629744338197D0
310	D35= -18.99932366302254D0
311	D41= -5.905188728329743D0
312	D42= 13.53022403646467D0
313	D43= -117.6778956422581D0
314	D44= 134.3962081008550D0
315	D45= 8.678995715052762D0
316	ETA1=23.D0/8.D0
317	ANU1= 0.9838473040915402D0
318	ANU2= 0.3969226768377252D0
319	AMU1= 0.6563374010466914D0
320	AMU3= 0.3372498196189311D0
321	ELSE
322	PRINT *, 'WRONG CHOICE OF <METH>'
323	END IF
324	POSNEG=SIGN(1.D0,XEND-X)
325	HMAX1=MIN(ABS(HMAX),ABS(XEND-X))
326	IF (ABS(H).LE.10.D0*UROUND) H=1.0D-6
327	H=MIN(ABS(H),HMAX1)
328	H=SIGN(H,POSNEG)
329	HOLD=H
330	CFAC=SAFE(1+2NIT)
331	NEWTRE=.FALSE.
332	REJECT=.FALSE.
333	FIRST=.TRUE.
334	FACCO1=1.D0
335	FACCO2=1.D0
336	FACCO3=1.D0
337	FACCO4=1.D0
338	FACCO5=1.D0
339	NSING=0
340	XOLD=X
341	IF (ITOL.EQ.0) THEN
342	DO 8 I=1,N
343	8 SCAL(I)=1.D0 / ( AbsTol(1)+RelTol(1)*DABS(Y(I)) )
344	ELSE
345	DO 9 I=1,N
346	9 SCAL(I)=1.D0 / ( AbsTol(I)+RelTol(I)*DABS(Y(I)) )
347	END IF
348
349	C --- BASIC INTEGRATION STEP
350	10 CONTINUE
351
352	C * * * * * * ***
353	C COMPUTATION OF THE JACOBIAN
354	C * * * * * * ***
355	NJAC=NJAC+1
356	CALL JAC(N,X,Y,FJAC)
357	CALJAC=.TRUE.
358	20 CONTINUE
359
360	C * * * * * * ***
361	C COMPUTE THE MATRIX E AND ITS DECOMPOSITION
362	C * * * * * * ***
363	FAC1=1.D0/(H*GAMMA)
364	IF (IMPLCT) THEN
365	print *, 'IMPLCT 4'
366	ELSE ! EXPLICIT SYSTEM
367	C --- THE MATRIX E (MAS=IDENTITY, JACOBIAN A FULL MATRIX)
368	c DO 526 J=1,N
369	c DO 525 I=1,N
370	c 525 E(I,J)=-FJAC(I,J)
371	c 526 E(J,J)=E(J,J)+FAC1
372	c CALL DEC(N,LE,E,IP,IER)
373	DO K=1,LU_NONZERO
374	E(K) = -FJAC(K)
375	END DO
376	DO I=1,N
377	IDG = LU_DIAG(I)
378	E(IDG) = E(IDG) + FAC1
379	END DO
380	CALL KppDecomp ( E, IER)
381
382	IF (IER.NE.0) GOTO 79
383	END IF
384	NDEC=NDEC+1
385	30 CONTINUE
386
387	IF (NSTEP.GT.NMAX.OR.X+.1D0*H.EQ.X.OR.ABS(H).LE.UROUND) GOTO 79
388	XPH=X+H
389	C --- LOOP FOR THE 5 STAGES
390	FACCO1=DMAX1(FACCO1,UROUND)**0.8D0
391	FACCO2=DMAX1(FACCO2,UROUND)**0.8D0
392	FACCO3=DMAX1(FACCO3,UROUND)**0.8D0
393	FACCO4=DMAX1(FACCO4,UROUND)**0.8D0
394	FACCO5=DMAX1(FACCO5,UROUND)**0.8D0
395
396	C * * * * * * ***
397	C STARTING VALUES FOR NEWTON ITERATION
398	C * * * * * * ***
399	DO 59 ISTAGE=1,5
400	IF (ISTAGE.EQ.1) THEN
401	XCH=X+GAMMA*H
402	IF (FIRST.OR.NEWTRE) THEN
403	DO 132 I=1,N
404	132 Z(I)=0.D0
405	ELSE
406	S=1.D0+GAMMA*H/HOLD
407	DO 232 I=1,N
408	c 232 Z(I) = 0.D0
409	232 Z(I)=S(CONT(I+NN)+S(CONT(I+NN2)+S*(CONT(I+NN3)
410	& +S*CONT(I+NN4))))-YHAT(I)
411
412	END IF
413	DO 31 I=1,N
414	31 G1(I)=0.D0
415	FACCON=FACCO1
416	END IF
417	IF (ISTAGE.EQ.2) THEN
418	XCH=X+C2*H
419	DO 131 I=1,N
420	Z1I=Z1(I)
421	Z(I)=ETA1*Z1I
422	131 G1(I)=ALPH21*Z1I
423	FACCON=FACCO2
424	END IF
425	IF (ISTAGE.EQ.3) THEN
426	XCH=X+C3*H
427	DO 231 I=1,N
428	Z1I=Z1(I)
429	Z2I=Z2(I)
430	Z(I)=ANU1Z1I+ANU2Z2I
431	231 G1(I)=ALPH31Z1I+ALPH32Z2I
432	FACCON=FACCO3
433	END IF
434	IF (ISTAGE.EQ.4) THEN
435	XCH=X+C4*H
436	DO 331 I=1,N
437	Z1I=Z1(I)
438	Z3I=Z3(I)
439	Z(I)=AMU1Z1I+AMU3Z3I
440	331 G1(I)=ALPH41Z1I+ALPH42Z2(I)+ALPH43*Z3I
441	FACCON=FACCO4
442	END IF
443	IF (ISTAGE.EQ.5) THEN
444	XCH=XPH
445	DO 431 I=1,N
446	Z1I=Z1(I)
447	Z2I=Z2(I)
448	Z3I=Z3(I)
449	Z4I=Z4(I)
450	Z(I)=E1Z1I+E2Z2I+E3Z3I+E4Z4I
451	YHAT(I)=Z(I)
452	431 G1(I)=ALPH51Z1I+ALPH52Z2I+ALPH53Z3I+ALPH54Z4I
453	FACCON=FACCO5
454	END IF
455
456
457
458	C * * * * * * * * * * ***
459	C LOOP FOR THE SIMPLIFIED NEWTON ITERATION
460	C * * * * * * * * * * ***
461	NEWT=0
462	THETA=ABS(THET)
463	IF (REJECT) THETA=2*ABS(THET)
464	40 CONTINUE
465	IF (NEWT.GE.NIT) THEN
466	H=H/2.D0
467	REJECT=.TRUE.
468	NEWTRE=.TRUE.
469	IF (CALJAC) GOTO 20
470	GOTO 10
471	END IF
472
473	C --- COMPUTE THE RIGHT-HAND SIDE
474	DO 41 I=1,N
475	H1(I)=G1(I)-Z(I)
476	41 CONT(I)=Y(I)+Z(I)
477	CALL FCN(N,XCH,CONT,F1)
478	NFCN=NFCN+1
479
480	C --- KppSolve THE LINEAR SYSTEMS
481	IF (IMPLCT) THEN
482	print *, 'IMPLCT 2'
483	ELSE
484	DO 345 I=1,N
485	345 F1(I)=H1(I)*FAC1+F1(I)
486	C CALL SOL(N,LE,E,F1,IP)
487	CALL KppSolve(E, F1)
488	END IF
489	NEWT=NEWT+1
490	DYNO=0.D0
491	C --- NORM 2 ---
492	DO 57 I=1,N
493	57 DYNO=DYNO+(F1(I)SCAL(I))*2
494	DYNO=DSQRT(DYNO/N)
495	C --- NORM INF ---
496	C DO 57 I=1,N
497	C 57 DYNO=DMAX1( DYNO, DABS(F1(I)*SCAL(I)) )
498
499
500	C --- BAD CONVERGENCE OR NUMBER OF ITERATIONS TO LARGE
501	IF (NEWT.GE.2.AND.NEWT.LT.NIT) THEN
502	THETA=DYNO/DYNOLD
503	IF (THETA.LT.0.99D0) THEN
504	FACCON=THETA/(1.0D0-THETA)
505	DYTH=FACCONDYNOTHETA**(NIT-1-NEWT)
506	QNEWT=DMAX1(1.0D-4,DMIN1(16.0D0,DYTH/FNEWT))
507	IF (QNEWT.GE.1.0D0) THEN
508	H=.8D0HQNEWT**(-1.0D0/(NIT-NEWT))
509	REJECT=.TRUE.
510	NEWTRE=.TRUE.
511	IF (CALJAC) GOTO 20
512	GOTO 10
513	END IF
514	ELSE
515	NEWTRE=.TRUE.
516	GOTO 78
517	END IF
518	END IF
519	DYNOLD=DYNO
520	DO 58 I=1,N
521	58 Z(I)=Z(I)+F1(I)
522	NSOL=NSOL+1
523	IF (FACCON*DYNO.GT.FNEWT) GOTO 40
524
525	C --- END OF SIMPILFIED NEWTON
526	IF (ISTAGE.EQ.1) THEN
527	DO I=1,N
528	Z1(I) = Z(I)
529	END DO
530	FACCO1=FACCON
531	END IF
532	IF (ISTAGE.EQ.2) THEN
533	DO I=1,N
534	Z2(I) = Z(I)
535	END DO
536	FACCO2=FACCON
537	END IF
538	IF (ISTAGE.EQ.3) THEN
539	DO I=1,N
540	Z3(I) = Z(I)
541	END DO
542	FACCO3=FACCON
543	END IF
544	IF (ISTAGE.EQ.4) THEN
545	DO I=1,N
546	Z4(I) = Z(I)
547	END DO
548	FACCO4=FACCON
549	END IF
550	IF (ISTAGE.EQ.5) THEN
551	DO I=1,N
552	Z5(I) = Z(I)
553	END DO
554	FACCO5=FACCON
555	END IF
556	59 CONTINUE
557
558
559	C * * * * * * ***
560	C ERROR ESTIMATION
561	C * * * * * * ***
562	NSTEP=NSTEP+1
563	IF (IMPLCT) THEN
564	print *,'IMPLCT 3'
565	ELSE
566	DO 461 I=1,N
567	461 CONT(I)=FAC1*(Z5(I)-YHAT(I))
568	END IF
569
570	CALL KppSolve(E, CONT)
571
572	ERR=0.D0
573	C ---- NORM 2 ---
574	DO 64 I=1,N
575	64 ERR=ERR+(CONT(I)SCAL(I))*2
576	ERR=DMAX1(DSQRT(ERR/N),1.D-10)
577
578	C ---- NORM INF ---
579	C DO 64 I=1,N
580	c 64 ERR=DMAX1( ERR, DABS( CONT(I)*SCAL(I) ) )
581
582	C --- COMPUTATION OF HNEW
583	C --- WE REQUIRE .25<=HNEW/H<=10.
584	FAC=DMIN1(SAFE,CFAC/(NEWT+2*NIT))
585	QUOT=DMAX1(.25D0,DMIN1(10.D0,(ERR)**.25D0/FAC))
586	HNEW= H/QUOT
587
588	C * * * * * * ***
589	C IS THE ERROR SMALL ENOUGH ?
590	C * * * * * * ***
591	IF (ERR.LT.1.D0) THEN
592	C --- STEP IS ACCEPTED
593	FIRST=.FALSE.
594	NACCPT=NACCPT+1
595	HOLD=H
596	XOLD=X
597	C --- COEFFICIENTS FOR CONTINUOUS SOLUTION
598	DO 74 I=1,N
599	Z1I=Z1(I)
600	Z2I=Z2(I)
601	Z3I=Z3(I)
602	Z4I=Z4(I)
603	Z5I=Z5(I)
604	CONT(I)=Y(I)
605	Y(I)=Y(I)+Z5I
606	CONT(I+NN) =D11Z1I+D12Z2I+D13Z3I+D14Z4I+D15*Z5I
607	CONT(I+NN2)=D21Z1I+D22Z2I+D23Z3I+D24Z4I+D25*Z5I
608	CONT(I+NN3)=D31Z1I+D32Z2I+D33Z3I+D34Z4I+D35*Z5I
609	CONT(I+NN4)=D41Z1I+D42Z2I+D43Z3I+D44Z4I+D45*Z5I
610	YHAT(I)=Z5I
611	IF (ITOL.EQ.0) THEN
612	SCAL(I)=1.D0/( AbsTol(1)+RelTol(1)*DABS(Y(I)) )
613	ELSE
614	SCAL(I)=1.D0/( AbsTol(I)+RelTol(I)*DABS(Y(I)) )
615	END IF
616	74 CONTINUE
617	X=XPH
618	CALJAC=.FALSE.
619	IF ((X-XEND)*POSNEG+UROUND.GT.0.D0) THEN
620	H=HOPT
621	IDID=1
622	RETURN
623	END IF
624	IF (IJAC.EQ.0) CALL FCN(N,X,Y,Y0)
625	NFCN=NFCN+1
626	HNEW=POSNEG*DMIN1(DABS(HNEW),HMAX1)
627	HOPT=HNEW
628	IF (REJECT) HNEW=POSNEG*DMIN1(DABS(HNEW),DABS(H))
629	REJECT=.FALSE.
630	NEWTRE=.FALSE.
631	IF ((X+HNEW/QUOT1-XEND)*POSNEG.GT.0.D0) THEN
632	H=XEND-X
633	ELSE
634	QT=HNEW/H
635	IF (THETA.LE.THET.AND.QT.GE.QUOT1.AND.QT.LE.QUOT2) GOTO 30
636	H = HNEW
637	END IF
638	IF (THETA.LE.THET) GOTO 20
639	GOTO 10
640
641	ELSE
642	C --- STEP IS REJECTED
643	REJECT=.TRUE.
644	IF (FIRST) THEN
645	H=H/10.D0
646	ELSE
647	H=HNEW
648	END IF
649	IF (NACCPT.GE.1) NREJCT=NREJCT+1
650	IF (CALJAC) GOTO 20
651	GOTO 10
652	END IF
653
654	C --- UNEXPECTED STEP-REJECTION
655	78 CONTINUE
656	IF (IER.NE.0) THEN
657	WRITE (6,*) ' MATRIX IS SINGULAR, IER=',IER,' X=',X,' H=',H
658	NSING=NSING+1
659	IF (NSING.GE.6) GOTO 79
660	END IF
661	H=H*0.5D0
662	REJECT=.TRUE.
663	IF (CALJAC) GOTO 20
664	GOTO 10
665
666	C --- FAIL EXIT
667	79 WRITE (6,979) X,H,IER
668	979 FORMAT(' EXIT OF SDIRK4 AT X=',D14.7,' H=',D14.7,' IER=',I4)
669	IDID=-1
670	RETURN
671	END
672	C
673
674
675	SUBROUTINE FUNC_CHEM(N, T, Y, P)
676	INCLUDE 'KPP_ROOT_Parameters.h'
677	INCLUDE 'KPP_ROOT_Global.h'
678	INTEGER N
679	KPP_REAL T, Told
680	KPP_REAL Y(NVAR), P(NVAR)
681	Told = TIME
682	TIME = T
683	CALL Update_SUN()
684	CALL Update_RCONST()
685	CALL Fun( Y, FIX, RCONST, P )
686	TIME = Told
687	RETURN
688	END
689
690
691	SUBROUTINE JAC_CHEM(N, T, Y, J)
692	INCLUDE 'KPP_ROOT_Parameters.h'
693	INCLUDE 'KPP_ROOT_Global.h'
694	INTEGER N
695	KPP_REAL Told, T
696	KPP_REAL Y(NVAR), J(LU_NONZERO)
697	Told = TIME
698	TIME = T
699	CALL Update_SUN()
700	CALL Update_RCONST()
701	CALL Jac_SP( Y, FIX, RCONST, J )
702	TIME = Told
703	RETURN
704	END
705

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source: palm/trunk/UTIL/chemistry/gasphase_preproc/kpp/int.modified_WCOPY/kpp_sdirk4.f

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