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stiffoptions.f90 @ 2696

Last change on this file since 2696 was 2696, checked in by kanani, 6 years ago
Merge of branch palm4u into trunk
File size: 68.9 KB

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1	! DVODE_F90 demonstration program
2	! Enforces nonnegativity on the Class F problems
3
4	! Toronto Stiff Test Set
5
6	! This program solves each of the thirty problems for several error
7	! tolerances using each of the dense, banded, and sparse solution
8	! options and with the numerical Jacobians formed using each of the
9	! original VODE algorithm and Doug Salane's JACSP. The ODEs are
10	! solved both in scaled and unscaled form. Scalar error tolerances
11	! are used for all problems even though this is not appropriate in
12	! some cases. The program takes 10-15 minutes to run because several
13	! thousand integrations are performed in all. Details of each
14	! integration are written to the output file 'stiffoptions.dat'.
15	! Summaries of the integration statistics may be found by searching
16	! on the string 'Individual'. There are several blocks of such summaries.
17	! When you run the program, the last line in the output file should
18	! read: 'No errors occurred.' Please contact one of the authors if
19	! any errors do occur.
20
21	! Reference:
22	! ALGORITHM 648, COLLECTED ALGORITHMS FROM ACM.
23	! TRANSACTIONS ON MATHEMATICAL SOFTWARE,
24	! VOL. 13, NO. 1, P. 28
25
26	! Caution:
27	! The original test routines are altered in this version.
28	! Some subroutine arguments, COMMON variables, and local
29	! variables have been moved to the following global header.
30	! You should obtain the original test suite from netlib
31	! if you plan to use the routines for other purposes.
32
33	MODULE STIFFSET
34
35	! Note:
36	! In this version ID and IID are defined in the main
37	! program demostiff (not in the Toronto routines).
38	! The other parameters are obtained by calling IVALU
39	! with a modified argument list.
40
41	IMPLICIT NONE
42	INTEGER IWT, N, ID, IID, NFCN, NJAC, NLUD
43	DOUBLE PRECISION W, DY
44	DIMENSION W(20), DY(400)
45
46	CONTAINS
47
48	SUBROUTINE DERIVS(NEQ,T,Y,YDOT)
49	! Define the system derivatives.
50	IMPLICIT NONE
51	INTEGER NEQ
52	DOUBLE PRECISION T, Y, YDOT
53	DIMENSION Y(NEQ), YDOT(NEQ)
54	CALL FCN(T,Y,YDOT)
55	RETURN
56	END SUBROUTINE DERIVS
57
58	SUBROUTINE JACD(NEQ,T,Y,ML,MU,PD,NROWPD)
59	! Load the Jacobian as a dense matrix.
60	IMPLICIT NONE
61	INTEGER NEQ, ML, MU, NROWPD, I, J
62	DOUBLE PRECISION T, Y, PD
63	DIMENSION Y(NEQ), PD(NROWPD,NEQ)
64	CALL PDERV(T,Y)
65	DO J = 1, NEQ
66	DO I = 1, NEQ
67	PD(I,J) = DY(I+(J-1)*NROWPD)
68	END DO
69	END DO
70	RETURN
71	END SUBROUTINE JACD
72
73	SUBROUTINE JACB(NEQ,T,Y,ML,MU,PD,NROWPD)
74	! Load the Jacobian as a banded matrix.
75	IMPLICIT NONE
76	INTEGER NEQ, ML, MU, NROWPD, I, J, K
77	DOUBLE PRECISION T, Y, PD
78	DIMENSION Y(NEQ), PD(NROWPD,NEQ)
79	CALL PDERV(T,Y)
80	DO J = 1, NEQ
81	DO I = 1, NEQ
82	K = I - J + MU + 1
83	PD(K,J) = DY(I+(J-1)*NEQ)
84	END DO
85	END DO
86	END SUBROUTINE JACB
87
88	SUBROUTINE JACS(NEQ,T,Y,IA,JA,NZ,P)
89	! Load the Jacobian as a sparse matrix.
90	IMPLICIT NONE
91	INTEGER NEQ, IA, JA, NZ, ML, MU, COL, ROW, I, NROWPD
92	! INTEGER NZSAVE
93	DOUBLE PRECISION T, Y, P
94	DIMENSION Y(), IA(), JA(), P()
95	IF (NZ<=0) THEN
96	NZ = NEQ*NEQ
97	RETURN
98	END IF
99	ML = NEQ - 1
100	MU = NEQ - 1
101	NROWPD = NEQ
102	CALL JACD(NEQ,T,Y,ML,MU,P,NROWPD)
103	IA(1) = 1
104	DO I = 1, NEQ
105	IA(I+1) = IA(I) + NEQ
106	END DO
107	I = 0
108	DO COL = 1, NEQ
109	I = NEQ*(COL-1)
110	DO ROW = 1, NEQ
111	I = I + 1
112	JA(I) = ROW
113	END DO
114	END DO
115	RETURN
116	END SUBROUTINE JACS
117
118	SUBROUTINE IVALU(XSTART,XEND,HBEGIN,HMAX,Y)
119
120	! ROUTINE TO PROVIDE THE INITIAL VALUES REQUIRED TO SPECIFY
121	! THE MATHEMATICAL PROBLEM AS WELL AS VARIOUS PROBLEM
122	! PARAMETERS REQUIRED BY THE TESTING PACKAGE. THE APPROPRIATE
123	! SCALING VECTOR IS ALSO INITIALISED IN CASE THIS OPTION IS
124	! SELECTED.
125
126	! PARAMETERS (OUTPUT)
127	! N - DIMENSION OF THE PROBLEM
128	! XSTART - INITIAL VALUE OF THE INDEPENDENT VARIABLE
129	! XEND - FINAL VALUE OF THE INDEPENDENT VARIABLE
130	! HBEGIN - APPROPRIATE STARTING STEPSIZE
131	! Y - VECTOR OF INITIAL CONDITIONS FOR THE DEPENDENT
132	! VARIABLES
133	! W - VECTOR OF WEIGHTS USED TO SCALE THE PROBLEM IF
134	! THIS OPTION IS SELECTED.
135
136	! PARAMETER (INPUT)
137	! IWT - FLAG TO INDICATE IF SCALED OPTION IS SELECTED
138	! ID - FLAG IDENTIFYING WHICH EQUATION IS BEING SOLVED
139
140	IMPLICIT NONE
141
142	! .. Scalar Arguments ..
143	DOUBLE PRECISION HBEGIN, HMAX, XEND, XSTART
144	! .. Array Arguments ..
145	DOUBLE PRECISION Y(20)
146	! .. Local Scalars ..
147	DOUBLE PRECISION XS
148	INTEGER I, IOUT, ITMP
149	! .. Data statements ..
150	DATA XS/0.D0/
151
152	! .. Executable Statements ..
153
154	XSTART = XS
155	! GOTO (40, 80, 120, 160, 20, 20, 20, 20, 20, 20, 200, 220, 220, &
156	! 220, 220, 20, 20, 20, 20, 20, 360, 400, 400, 400, 400, 20, 20, 20,&
157	! 20, 20, 540, 580, 600, 640, 660, 680, 20, 20, 20, 20, 700, 740, &
158	! 760, 780, 800, 20, 20, 20, 20, 20, 840, 860, 880, 900, 920) ID
159	GOTO (20,30,40,50,10,10,10,10,10,10,60,70,70,70,70,10,10,10,10,10, &
160	130,140,140,140,140,10,10,10,10,10,200,210,220,230,240,250,10,10,10, &
161	10,260,270,280,290,300,10,10,10,10,10,310,320,330,340,350) ID
162	10 IOUT = 6
163	WRITE (IOUT,FMT=90000) ID
164	STOP
165
166	! PROBLEM CLASS A - LINEAR WITH REAL EIGENVALUES
167
168	20 CONTINUE
169	! PROBLEM A1
170	N = 4
171	W(1) = 0.100D+01
172	W(2) = 0.100D+01
173	W(3) = 0.100D+01
174	W(4) = 0.100D+01
175	XEND = 20.D0
176	HBEGIN = 1.0D-2
177	HMAX = 20.D0
178	DO I = 1, N
179	Y(I) = 1.0D0
180	END DO
181	GOTO 360
182
183	30 CONTINUE
184	! PROBLEM A2
185	N = 9
186	W(1) = 0.100D+00
187	W(2) = 0.200D+00
188	W(3) = 0.300D+00
189	W(4) = 0.400D+00
190	W(5) = 0.500D+00
191	W(6) = 0.600D+00
192	W(7) = 0.700D+00
193	W(8) = 0.800D+00
194	W(9) = 0.900D+00
195	XEND = 120.D0
196	HBEGIN = 5.D-4
197	HMAX = 120.D0
198	DO I = 1, N
199	Y(I) = 0.D0
200	END DO
201	GOTO 360
202
203	40 CONTINUE
204	! PROBLEM A3
205	N = 4
206	W(1) = 0.100D+01
207	W(2) = 0.100D+01
208	W(3) = 0.782D+01
209	W(4) = 0.100D+01
210	HBEGIN = 1.D-5
211	XEND = 20.D0
212	HMAX = 20.D0
213	DO I = 1, N
214	Y(I) = 1.D0
215	END DO
216	GOTO 360
217
218	50 CONTINUE
219	! PROBLEM A4
220	N = 10
221	W(1) = 0.100D+01
222	W(2) = 0.100D+01
223	W(3) = 0.100D+01
224	W(4) = 0.100D+01
225	W(5) = 0.100D+01
226	W(6) = 0.100D+01
227	W(7) = 0.100D+01
228	W(8) = 0.100D+01
229	W(9) = 0.100D+01
230	W(10) = 0.100D+01
231	XEND = 1.D0
232	HBEGIN = 1.D-5
233	HMAX = 1.D0
234	DO I = 1, N
235	Y(I) = 1.D0
236	END DO
237	GOTO 360
238
239	! PROBLEM CLASS B - LINEAR WITH NON-REAL EIGENVALUES
240
241	60 CONTINUE
242	! PROBLEM B1
243	N = 4
244	W(1) = 0.100D+01
245	W(2) = 0.859D+01
246	W(3) = 0.100D+01
247	W(4) = 0.322D+02
248	XEND = 20.D0
249	HBEGIN = 7.D-3
250	HMAX = 20.D0
251	Y(1) = 1.D0
252	Y(2) = 0.D0
253	Y(3) = 1.D0
254	Y(4) = 0.D0
255	GOTO 360
256
257	70 CONTINUE
258	! PROBLEM B2, B3, B4, B5
259	N = 6
260	ITMP = IID - 1
261	GOTO (80,90,100,110) ITMP
262	80 CONTINUE
263	W(1) = 0.100D+01
264	W(2) = 0.100D+01
265	W(3) = 0.100D+01
266	W(4) = 0.100D+01
267	W(5) = 0.100D+01
268	W(6) = 0.100D+01
269	GOTO 120
270	90 CONTINUE
271	W(1) = 0.100D+01
272	W(2) = 0.100D+01
273	W(3) = 0.100D+01
274	W(4) = 0.100D+01
275	W(5) = 0.100D+01
276	W(6) = 0.100D+01
277	GOTO 120
278	100 CONTINUE
279	W(1) = 0.112D+01
280	W(2) = 0.100D+01
281	W(3) = 0.100D+01
282	W(4) = 0.100D+01
283	W(5) = 0.100D+01
284	W(6) = 0.100D+01
285	GOTO 120
286	110 CONTINUE
287	W(1) = 0.131D+01
288	W(2) = 0.112D+01
289	W(3) = 0.100D+01
290	W(4) = 0.100D+01
291	W(5) = 0.100D+01
292	W(6) = 0.100D+01
293	120 CONTINUE
294	XEND = 20.D0
295	HBEGIN = 1.D-2
296	HMAX = 20.D0
297	DO I = 1, N
298	Y(I) = 1.D0
299	END DO
300	GOTO 360
301
302	! PROBLEM CLASS C - NON-LINEAR COUPLING FROM
303	! STEADY STATE TO TRANSIENT
304
305	130 CONTINUE
306	! PROBLEM C1
307	N = 4
308	W(1) = 0.102D+01
309	W(2) = 0.103D+01
310	W(3) = 0.100D+01
311	W(4) = 0.100D+01
312	XEND = 20.D0
313	HBEGIN = 1.D-2
314	HMAX = 20.D0
315	DO I = 1, N
316	Y(I) = 1.D0
317	END DO
318	GOTO 360
319
320	140 CONTINUE
321	! PROBLEM C2, C3, C4, C5
322	N = 4
323	ITMP = IID - 1
324	GOTO (150,160,170,180) ITMP
325	150 CONTINUE
326	W(1) = 0.200D+01
327	W(2) = 0.100D+01
328	W(3) = 0.100D+01
329	W(4) = 0.100D+01
330	GOTO 190
331	160 CONTINUE
332	W(1) = 0.200D+01
333	W(2) = 0.100D+01
334	W(3) = 0.100D+01
335	W(4) = 0.100D+01
336	GOTO 190
337	170 CONTINUE
338	W(1) = 0.200D+01
339	W(2) = 0.400D+01
340	W(3) = 0.200D+02
341	W(4) = 0.420D+03
342	GOTO 190
343	180 CONTINUE
344	W(1) = 0.200D+01
345	W(2) = 0.800D+01
346	W(3) = 0.136D+03
347	W(4) = 0.371D+05
348	190 CONTINUE
349	XEND = 20.D0
350	HBEGIN = 1.D-2
351	HMAX = 20.D0
352	DO I = 1, N
353	Y(I) = 1.D0
354	END DO
355	GOTO 360
356
357	! PROBLEM CLASS D - NON-LINEAR WITH REAL EIGENVALUES
358
359	200 CONTINUE
360	! PROBLEM D1
361	N = 3
362	W(1) = 0.223D+02
363	W(2) = 0.271D+02
364	W(3) = 0.400D+03
365	XEND = 400.D0
366	HBEGIN = 1.7D-2
367	HMAX = 400.D0
368	DO I = 1, N
369	Y(I) = 0.D0
370	END DO
371	GOTO 360
372
373	210 CONTINUE
374	! PROBLEM D2
375	N = 3
376	W(1) = 0.100D+01
377	W(2) = 0.365D+00
378	W(3) = 0.285D+02
379	XEND = 40.D0
380	HBEGIN = 1.D-5
381	HMAX = 40.D0
382	Y(1) = 1.D0
383	Y(2) = 0.D0
384	Y(3) = 0.D0
385	GOTO 360
386
387	220 CONTINUE
388	! PROBLEM D3
389	N = 4
390	W(1) = 0.100D+01
391	W(2) = 0.100D+01
392	W(3) = 0.360D+00
393	W(4) = 0.485D+00
394	XEND = 20.D0
395	HBEGIN = 2.5D-5
396	HMAX = 20.D0
397	DO I = 1, 2
398	Y(I) = 1.D0
399	Y(I+2) = 0.D0
400	END DO
401	GOTO 360
402
403	230 CONTINUE
404	! PROBLEM D4
405	N = 3
406	W(1) = 0.100D+01
407	W(2) = 0.142D+01
408	W(3) = 0.371D-05
409	XEND = 50.D0
410	HBEGIN = 2.9D-4
411	HMAX = 50.D0
412	Y(1) = 1.D0
413	Y(2) = 1.D0
414	Y(3) = 0.D0
415	GOTO 360
416
417	240 CONTINUE
418	! PROBLEM D5
419	N = 2
420	W(1) = 0.992D+00
421	W(2) = 0.984D+00
422	XEND = 1.D2
423	HBEGIN = 1.D-4
424	HMAX = 1.D2
425	Y(1) = 0.D0
426	Y(2) = 0.D0
427	GOTO 360
428
429	250 CONTINUE
430	! PROBLEM D6
431	N = 3
432	W(1) = 0.100D+01
433	W(2) = 0.148D+00
434	W(3) = 0.577D-07
435	XEND = 1.D0
436	HBEGIN = 3.3D-8
437	HMAX = 1.D0
438	Y(1) = 1.D0
439	Y(2) = 0.D0
440	Y(3) = 0.D0
441	GOTO 360
442
443	! PROBLEM CLASS E - NON-LINEAR WITH NON-REAL EIGENVALUES
444
445	260 CONTINUE
446	! PROBLEM E1
447	N = 4
448	W(1) = 0.100D-07
449	W(2) = 0.223D-06
450	W(3) = 0.132D-04
451	W(4) = 0.171D-02
452	XEND = 1.D0
453	HBEGIN = 6.8D-3
454	HMAX = 1.D0
455	DO I = 1, N
456	Y(I) = 0.D0
457	END DO
458	GOTO 360
459
460	270 CONTINUE
461	! PROBLEM E2
462	N = 2
463	W(1) = 0.202D+01
464	W(2) = 0.764D+01
465	XEND = 1.D1
466	HBEGIN = 1.D-3
467	HMAX = 1.D1
468	Y(1) = 2.D0
469	Y(2) = 0.D0
470	GOTO 360
471
472	280 CONTINUE
473	! PROBLEM E3
474	N = 3
475	W(1) = 0.163D+01
476	W(2) = 0.160D+01
477	W(3) = 0.263D+02
478	XEND = 5.D2
479	HBEGIN = .2D-1
480	HMAX = 5.D2
481	Y(1) = 1.D0
482	Y(2) = 1.D0
483	Y(3) = 0.D0
484	GOTO 360
485
486	290 CONTINUE
487	! PROBLEM E4
488	N = 4
489	W(1) = 0.288D+02
490	W(2) = 0.295D+02
491	W(3) = 0.155D+02
492	W(4) = 0.163D+02
493	XEND = 1.D3
494	HBEGIN = 1.D-3
495	HMAX = 1.D3
496	Y(1) = 0.D0
497	Y(2) = -2.D0
498	Y(3) = -1.D0
499	Y(4) = -1.D0
500	GOTO 360
501
502	300 CONTINUE
503	! PROBLEM E5
504	N = 4
505	W(1) = 0.176D-02
506	W(2) = 0.146D-09
507	W(3) = 0.827D-11
508	W(4) = 0.138D-09
509	XEND = 1.D3
510	HBEGIN = 5.D-5
511	HMAX = 1.D3
512	Y(1) = 1.76D-3
513	DO I = 2, N
514	Y(I) = 0.D0
515	END DO
516	GOTO 360
517
518	! PROBLEM CLASS F - CHEMICAL KINETICS EQUATIONS
519
520	310 CONTINUE
521	! PROBLEM F1
522	N = 4
523	W(1) = 0.121D+04
524	W(2) = 0.835D-01
525	W(3) = 0.121D+04
526	W(4) = 0.100D+00
527	HMAX = 1.D3
528	HBEGIN = 1.D-4
529	XEND = 1.D3
530	Y(1) = 761.D0
531	Y(2) = 0.D0
532	Y(3) = 600.D0
533	Y(4) = .1D0
534	GOTO 360
535
536	320 CONTINUE
537	! PROBLEM F2
538	N = 2
539	W(1) = 0.100D+01
540	W(2) = 0.253D-02
541	HMAX = 240.D0
542	HBEGIN = 1.D-2
543	XEND = 240.D0
544	Y(1) = 1.0D0
545	Y(2) = 0.D0
546	GOTO 360
547
548	330 CONTINUE
549	! PROBLEM F3
550	N = 5
551	W(1) = 0.400D-05
552	W(2) = 0.100D-05
553	W(3) = 0.374D-08
554	W(4) = 0.765D-06
555	W(5) = 0.324D-05
556	HBEGIN = 1.D-6
557	HBEGIN = 1.D-10
558	HMAX = 100.D0
559	XEND = 100.D0
560	Y(1) = 4.D-6
561	Y(2) = 1.D-6
562	Y(3) = 0.0D0
563	Y(4) = 0.0D0
564	Y(5) = 0.0D0
565	GOTO 360
566
567	340 CONTINUE
568	! PROBLEM F4
569	N = 3
570	W(1) = 0.118D+06
571	W(2) = 0.177D+04
572	W(3) = 0.313D+05
573	HBEGIN = 1.D-3
574	! HMAX = 50.D0
575	HMAX = 1.D0
576	XEND = 300.D0
577	Y(1) = 4.D0
578	Y(2) = 1.1D0
579	Y(3) = 4.D0
580	GOTO 360
581
582	350 CONTINUE
583	! PROBLEM F5
584	N = 4
585	W(1) = 0.336D-06
586	W(2) = 0.826D-02
587	W(3) = 0.619D-02
588	W(4) = 0.955D-05
589	HBEGIN = 1.D-7
590	HMAX = 100.D0
591	XEND = 100.D0
592	Y(1) = 3.365D-7
593	Y(2) = 8.261D-3
594	Y(3) = 1.642D-3
595	Y(4) = 9.380D-6
596	360 CONTINUE
597	IF (IWT<0) GOTO 370
598	DO I = 1, N
599	Y(I) = Y(I)/W(I)
600	END DO
601	370 CONTINUE
602	RETURN
603
604	90000 FORMAT (' AN INVALID INTERNAL PROBLEM ID OF ',I4, &
605	' WAS FOUND BY THE IVALU ROUTINE',' RUN TERMINATED. CHECK THE DATA.' &
606	)
607	END SUBROUTINE IVALU
608
609	SUBROUTINE EVALU(Y)
610
611	! ROUTINE TO PROVIDE THE 'TRUE' SOLUTION OF THE DIFFERENTIAL
612	! EQUATION EVALUATED AT THE ENDPOINT OF THE INTEGRATION.
613
614	! 1986 REVISION: SOME VERY SMALL CONSTANTS HAVE BEEN RECAST IN THE
615	! (NOT SO SMALL CONST)/(1.E38) TO AVOID COMPILE-TIME UNDERFLOW ERROR
616	! IT IS ASSUMED 1E+38 WON'T OVERFLOW.
617	! PARAMETER (OUTPUT)
618	! Y - THE TRUE SOLUTION VECTOR EVALUATED AT THE ENDPOINT
619
620	! PARAMETERS (INPUT)
621	! N - DIMENSION OF THE PROBLEM
622	! W - VECTOR OF WEIGHTS USED TO SCALE THE PROBLEM
623	! IF THIS OPTION IS SELECTED
624	! IWT - FLAG USED TO SIGNAL WHEN THE SCALED PROBLEM IS
625	! BEING SOLVED
626	! ID - FLAG USED TO INDICATE WHICH EQUATION IS BEING
627	! SOLVED
628
629	IMPLICIT NONE
630
631	! .. Parameters ..
632	DOUBLE PRECISION TENE38
633	PARAMETER (TENE38=1.D38)
634	! .. Array Arguments ..
635	DOUBLE PRECISION Y(20)
636	! .. Local Scalars ..
637	INTEGER I
638
639	! .. Executable Statements ..
640
641	! GOTO (20, 40, 60, 80, 620, 620, 620, 620, 620, 620, 100, 120, 140,&
642	! 160, 180, 620, 620, 620, 620, 620, 200, 220, 240, 260, 280, 620, &
643	! 620, 620, 620, 620, 300, 320, 340, 360, 380, 400, 620, 620, 620, &
644	! 620, 420, 440, 460, 480, 500, 620, 620, 620, 620, 620, 520, 540, &
645	! 560, 580, 600, 620, 620, 620, 620, 620) ID
646	GOTO (10,20,30,40,310,310,310,310,310,310,50,60,70,80,90,310,310,310, &
647	310,310,100,110,120,130,140,310,310,310,310,310,150,160,170,180,190, &
648	200,310,310,310,310,210,220,230,240,250,310,310,310,310,310,260,270, &
649	280,290,300,310,310,310,310,310) ID
650	GOTO 310
651
652	! PROBLEM CLASS A
653
654	! PROBLEM A1
655	10 Y(1) = 4.539992969929191D-05
656	Y(2) = 2.061153036149920D-09
657	Y(3) = 2.823006338263857D-18/TENE38
658	Y(4) = 5.235792540515384D-14/TENE38
659	GOTO 310
660
661	! PROBLEM A2
662	20 Y(1) = 9.999912552999704D-02
663	Y(2) = 1.999982511586291D-01
664	Y(3) = 2.999975543202422D-01
665	Y(4) = 3.999971057541257D-01
666	Y(5) = 4.999969509963023D-01
667	Y(6) = 5.999971057569546D-01
668	Y(7) = 6.999975543256127D-01
669	Y(8) = 7.999982511659962D-01
670	Y(9) = 8.999991255386128D-01
671	GOTO 310
672
673	! PROBLEM A3
674	30 Y(1) = -1.353352661867235D-03
675	Y(2) = 1.368526917891521D-02
676	Y(3) = 1.503725348455117D+00
677	Y(4) = 1.353352832366099D-01
678	GOTO 310
679
680	! PROBLEM A4
681	40 Y(1) = 3.678794411714325D-01
682	Y(2) = 1.265870722340194D-14
683	Y(3) = 1.911533219339204D-04/TENE38
684	Y(4) = 2.277441666729596D-17/TENE38
685	Y(5) = 0.0D0
686	Y(6) = 0.0D0
687	Y(7) = 0.0D0
688	Y(8) = 0.0D0
689	Y(9) = 0.0D0
690	Y(10) = 0.0D0
691	GOTO 310
692
693	! PROBLEM CLASS B
694
695	! PROBLEM B1
696	50 Y(1) = 1.004166730990124D-09
697	Y(2) = 1.800023280346500D-08
698	Y(3) = 0.0D0
699	Y(4) = -6.042962877027475D-03/TENE38/TENE38
700	GOTO 310
701
702	! PROBLEM B2
703	60 Y(1) = 6.181330838820067D-31
704	Y(2) = 8.963657877626303D-31
705	Y(3) = 2.738406773453261D-27
706	Y(4) = 2.061153063164016D-09
707	Y(5) = 4.539992973654118D-05
708	Y(6) = 1.353352832365270D-01
709	GOTO 310
710
711	! PROBLEM B3
712	70 Y(1) = -1.076790816984970D-28
713	Y(2) = 5.455007683862160D-28
714	Y(3) = 2.738539964946867D-27
715	Y(4) = 2.061153071123456D-09
716	Y(5) = 4.539992974611305D-05
717	Y(6) = 1.353352832365675D-01
718	GOTO 310
719
720	! PROBLEM B4
721	80 Y(1) = 1.331242472678293D-22
722	Y(2) = -2.325916064237926D-22
723	Y(3) = 1.517853928534857D-35
724	Y(4) = 2.061152428936651D-09
725	Y(5) = 4.539992963392291D-05
726	Y(6) = 1.353352832363442D-01
727	GOTO 310
728
729	! PROBLEM B5
730	90 Y(1) = -3.100634584292190D-14
731	Y(2) = 3.862788998076547D-14
732	Y(3) = 1.804851385304217D-35
733	Y(4) = 2.061153622425655D-09
734	Y(5) = 4.539992976246673D-05
735	Y(6) = 1.353352832366126D-01
736	GOTO 310
737
738	! PROBLEM CLASS C
739
740	! PROBLEM C1
741	100 Y(1) = 4.003223925456179D-04
742	Y(2) = 4.001600000000000D-04
743	Y(3) = 4.000000000000000D-04
744	Y(4) = 2.000000000000000D-02
745	GOTO 310
746
747	! PROBLEM C2
748	110 Y(1) = 1.999999997938994D+00
749	Y(2) = 3.999999990839974D-02
750	Y(3) = 4.001599991537078D-02
751	Y(4) = 4.003201271914461D-02
752	GOTO 310
753
754	! PROBLEM C3
755	120 Y(1) = 1.999999997939167D+00
756	Y(2) = 3.999999990840744D-01
757	Y(3) = 4.159999990793773D-01
758	Y(4) = 4.333055990159567D-01
759	GOTO 310
760
761	! PROBLEM C4
762	130 Y(1) = 1.999999997938846D+00
763	Y(2) = 3.999999990839318D+00
764	Y(3) = 1.999999991637941D+01
765	Y(4) = 4.199999965390368D+02
766	GOTO 310
767
768	! PROBLEM C5
769	140 Y(1) = 1.999999997938846D+00
770	Y(2) = 7.999999981678634D+00
771	Y(3) = 1.359999993817714D+02
772	Y(4) = 3.712799965967762D+04
773	GOTO 310
774
775	! PROBLEM CLASS D
776
777	! PROBLEM D1
778	150 Y(1) = 2.224222010616901D+01
779	Y(2) = 2.711071334484136D+01
780	Y(3) = 3.999999999999999D+02
781	GOTO 310
782
783	! PROBLEM D2
784	160 Y(1) = 7.158270687193941D-01
785	Y(2) = 9.185534764557338D-02
786	Y(3) = 2.841637457458413D+01
787	GOTO 310
788
789	! PROBLEM D3
790	170 Y(1) = 6.397604446889910D-01
791	Y(2) = 5.630850708287990D-03
792	Y(3) = 3.602395553110090D-01
793	Y(4) = 3.170647969903515D-01
794	GOTO 310
795
796	! PROBLEM D4
797	180 Y(1) = 5.976546980673215D-01
798	Y(2) = 1.402343408546138D+00
799	Y(3) = -1.893386540441913D-06
800	GOTO 310
801
802	! PROBLEM D5
803	190 Y(1) = -9.916420698713913D-01
804	Y(2) = 9.833363588544478D-01
805	GOTO 310
806
807	! PROBLEM D6
808	200 Y(1) = 8.523995440749948D-01
809	Y(2) = 1.476003981941319D-01
810	Y(3) = 5.773087333950041D-08
811	GOTO 310
812
813	! PROBLEM CLASS E
814
815	! PROBLEM E1
816	210 Y(1) = 1.000000000000012D-08
817	Y(2) = -1.625323873316817D-19
818	Y(3) = 2.025953375595861D-17
819	Y(4) = -1.853149807630002D-15
820	GOTO 310
821
822	! PROBLEM E2
823	220 Y(1) = -1.158701266031984D+00
824	Y(2) = 4.304698089780476D-01
825	GOTO 310
826
827	! PROBLEM E3
828	230 Y(1) = 4.253052197643089D-03
829	Y(2) = 5.317019548450387D-03
830	Y(3) = 2.627647748753926D+01
831	GOTO 310
832
833	! PROBLEM E4
834	240 Y(1) = 1.999999977523654D+01
835	Y(2) = -2.000000022476345D+01
836	Y(3) = -2.247634567084293D-07
837	Y(4) = 2.247634567084293D-07
838	GOTO 310
839
840	! PROBLEM E5
841	250 Y(1) = 1.618076919919600D-03
842	Y(2) = 1.382236955418478D-10
843	Y(3) = 8.251573436034144D-12
844	Y(4) = 1.299721221058136D-10
845	GOTO 310
846
847	! PROBLEM CLASS F
848
849	! PROBLEM F1
850	260 Y(1) = 1.211129474696585D+03
851	Y(2) = 1.271123619113051D-05
852	Y(3) = 1.208637804660361D+03
853	Y(4) = 3.241981171933418D-04
854	GOTO 310
855
856	! PROBLEM F2
857	270 Y(1) = 3.912699122292088D-01
858	Y(2) = 1.329964166084866D-03
859	GOTO 310
860
861	! PROBLEM F3
862	280 Y(1) = 3.235910070806680D-13
863	Y(2) = 2.360679774997897D-07
864	Y(3) = 7.639319089351045D-14
865	Y(4) = 7.639319461070194D-07
866	Y(5) = 3.236067653908783D-06
867	GOTO 310
868
869	! PROBLEM F4
870	290 Y(1) = 4.418303324022590D+00
871	Y(2) = 1.290244712916425D+00
872	Y(3) = 3.019282584050490D+00
873	GOTO 310
874
875	! PROBLEM F5
876	300 Y(1) = 1.713564284690712D-07
877	Y(2) = 3.713563071160676D-03
878	Y(3) = 6.189271785267793D-03
879	Y(4) = 9.545143571530929D-06
880	310 CONTINUE
881	IF (IWT<0) GOTO 320
882	DO I = 1, N
883	Y(I) = Y(I)/W(I)
884	END DO
885	320 CONTINUE
886	RETURN
887	END SUBROUTINE EVALU
888
889	SUBROUTINE FCN(X,Y,YP)
890
891	! ROUTINE TO EVALUATE THE DERIVATIVE F(X,Y) CORRESPONDING TO
892	! THE DIFFERENTIAL EQUATION:
893	! DY/DX = F(X,Y) .
894	! THE ROUTINE STORES THE VECTOR OF DERIVATIVES IN YP(*). THE
895	! PARTICULAR EQUATION BEING INTEGRATED IS INDICATED BY THE
896	! VALUE OF THE FLAG ID WHICH IS PASSED THROUGH COMMON. THE
897	! DIFFERENTIAL EQUATION IS SCALED BY THE WEIGHT VECTOR W(*)
898	! IF THIS OPTION HAS BEEN SELECTED (IF SO IT IS SIGNALLED
899	! BY THE FLAG IWT).
900
901	IMPLICIT NONE
902
903	! .. Scalar Arguments ..
904	DOUBLE PRECISION X
905	! .. Array Arguments ..
906	DOUBLE PRECISION Y(20), YP(20)
907	! .. Local Scalars ..
908	DOUBLE PRECISION F, Q, S, SUM, T, TEMP, XTEMP
909	INTEGER I
910	! .. Local Arrays ..
911	DOUBLE PRECISION BPARM(4), CPARM(4), VECT1(4), VECT2(4), YTEMP(20)
912	! .. Data statements ..
913	DATA BPARM/3.D0, 8.D0, 25.D0, 1.D2/
914	DATA CPARM/1.D-1, 1.D0, 1.D1, 2.D1/
915
916	! .. Executable Statements ..
917
918	NFCN = NFCN + 1
919	IF (IWT<0) GOTO 10
920	DO I = 1, N
921	YTEMP(I) = Y(I)
922	Y(I) = Y(I)*W(I)
923	END DO
924	10 CONTINUE
925	GOTO (20,30,40,50,260,260,260,260,260,260,60,70,70,70,70,260,260,260, &
926	260,260,80,90,90,90,90,260,260,260,260,260,100,110,120,130,140,150, &
927	260,260,260,260,160,170,180,190,200,260,260,260,260,260,210,220,230, &
928	240,250) ID
929	GOTO 260
930
931	! PROBLEM CLASS A - LINEAR WITH REAL EIGENVALUES
932
933	! PROBLEM A1
934	20 YP(1) = -.5D0*Y(1)
935	YP(2) = -1.D0*Y(2)
936	YP(3) = -1.D2*Y(3)
937	YP(4) = -9.D1*Y(4)
938	GOTO 260
939
940	! PROBLEM A2
941	30 YP(1) = -1.8D3Y(1) + 9.D2Y(2)
942	DO I = 2, 8
943	YP(I) = Y(I-1) - 2.D0*Y(I) + Y(I+1)
944	END DO
945	YP(9) = 1.D3Y(8) - 2.D3Y(9) + 1.D3
946	GOTO 260
947
948	! PROBLEM A3
949	40 YP(1) = -1.D4Y(1) + 1.D2Y(2) - 1.D1Y(3) + 1.D0Y(4)
950	YP(2) = -1.D3Y(2) + 1.D1Y(3) - 1.D1*Y(4)
951	YP(3) = -1.D0Y(3) + 1.D1Y(4)
952	YP(4) = -1.D-1*Y(4)
953	GOTO 260
954
955	! PROBLEM A4
956	50 DO I = 1, 10
957	YP(I) = -REAL(I)*5Y(I)
958	END DO
959	GOTO 260
960
961	! PROBLEM CLASS B - LINEAR WITH NON-REAL EIGENVALUES
962
963	! PROBLEM B1
964	60 YP(1) = -Y(1) + Y(2)
965	YP(2) = -1.D2*Y(1) - Y(2)
966	YP(3) = -1.D2*Y(3) + Y(4)
967	YP(4) = -1.D4Y(3) - 1.D2Y(4)
968	GOTO 260
969
970	! PROBLEMS B2, B3, B4, B5
971	70 YP(1) = -1.D1Y(1) + BPARM(IID-1)Y(2)
972	YP(2) = -BPARM(IID-1)Y(1) - 1.D1Y(2)
973	YP(3) = -4.D0*Y(3)
974	YP(4) = -1.D0*Y(4)
975	YP(5) = -.5D0*Y(5)
976	YP(6) = -.1D0*Y(6)
977	GOTO 260
978
979	! PROBLEM CLASS C - NON-LINEAR COUPLING FROM
980	! STEADY STATE TO TRANSIENT
981
982	! PROBLEM C1
983	80 YP(1) = -Y(1) + (Y(2)Y(2)+Y(3)Y(3)+Y(4)*Y(4))
984	YP(2) = -1.D1Y(2) + 1.D1(Y(3)Y(3)+Y(4)Y(4))
985	YP(3) = -4.D1Y(3) + 4.D1Y(4)*Y(4)
986	YP(4) = -1.D2*Y(4) + 2.D0
987	GOTO 260
988
989	! PROBLEMS C2, C3, C4, C5
990	90 YP(1) = -Y(1) + 2.D0
991	YP(2) = -1.D1Y(2) + CPARM(IID-1)Y(1)*Y(1)
992	YP(3) = -4.D1Y(3) + (Y(1)Y(1)+Y(2)Y(2))CPARM(IID-1)*4.D0
993	YP(4) = (Y(1)Y(1)+Y(2)Y(2)+Y(3)Y(3))CPARM(IID-1)1.D1 - 1.D2Y(4)
994	GOTO 260
995
996	! PROBLEM CLASS D - NON-LINEAR WITH REAL EIGENVALUES
997
998	! PROBLEM D1
999	100 YP(1) = .2D0Y(2) - .2D0Y(1)
1000	YP(2) = 1.D1Y(1) - (6.D1-.125D0Y(3))Y(2) + .125D0Y(3)
1001	YP(3) = 1.D0
1002	GOTO 260
1003
1004	! PROBLEM D2
1005	110 YP(1) = -.04D0Y(1) + .01D0Y(2)*Y(3)
1006	YP(2) = 4.D2Y(1) - 1.D2Y(2)Y(3) - 3.D3Y(2)**2
1007	YP(3) = 3.D1Y(2)*2
1008	GOTO 260
1009
1010	! PROBLEM D3
1011	120 YP(1) = Y(3) - 1.D2Y(1)Y(2)
1012	YP(3) = -YP(1)
1013	YP(4) = -Y(4) + 1.D4Y(2)*2
1014	YP(2) = YP(1) - YP(4) + Y(4) - 1.D4Y(2)*2
1015	GOTO 260
1016
1017	! PROBLEM D4
1018	130 YP(1) = -.013D0Y(1) - 1.D3Y(1)*Y(3)
1019	YP(2) = -2.5D3Y(2)Y(3)
1020	YP(3) = YP(1) + YP(2)
1021	GOTO 260
1022
1023	! PROBLEM D5
1024	140 XTEMP = .01D0 + Y(1) + Y(2)
1025	YP(1) = .01D0 - XTEMP(1.D0+(Y(1)+1.D3)(Y(1)+1.D0))
1026	YP(2) = .01D0 - XTEMP(1.D0+Y(2)*2)
1027	GOTO 260
1028
1029	! PROBLEM D6
1030	150 YP(1) = -Y(1) + 1.D8Y(3)(1.D0-Y(1))
1031	YP(2) = -1.D1Y(2) + 3.D7Y(3)*(1.D0-Y(2))
1032	YP(3) = -YP(1) - YP(2)
1033	GOTO 260
1034
1035	! PROBLEM CLASS E - NON-LINEAR WITH NON-REAL EIGENVALUES
1036
1037	! PROBLEM E1
1038	160 YP(1) = Y(2)
1039	YP(2) = Y(3)
1040	YP(3) = Y(4)
1041	YP(4) = (Y(1)*2-SIN(Y(1))-1.D8)Y(1) + (Y(2)Y(3)/(Y(1)*2+1.D0)-4.D6 &
1042	)Y(2) + (1.D0-6.D4)Y(3) + (1.D1EXP(-Y(4)2)-4.D2)Y(4) + 1.D0
1043	GOTO 260
1044
1045	! PROBLEM E2
1046	170 YP(1) = Y(2)
1047	YP(2) = 5.D0Y(2) - 5.D0Y(1)Y(1)Y(2) - Y(1)
1048	GOTO 260
1049
1050	! PROBLEM E3
1051	180 YP(1) = -55.D0Y(1) - Y(3)Y(1) + 65.D0*Y(2)
1052	YP(2) = .785D-1Y(1) - .785D-1Y(2)
1053	YP(3) = .1D0*Y(1)
1054	GOTO 260
1055
1056	! PROBLEM E4
1057	190 SUM = Y(1) + Y(2) + Y(3) + Y(4)
1058	DO I = 1, 4
1059	VECT2(I) = -Y(I) + .5D0*SUM
1060	END DO
1061	VECT1(1) = .5D0(VECT2(1)2-VECT2(2)*2)
1062	VECT1(2) = VECT2(1)*VECT2(2)
1063	VECT1(3) = VECT2(3)**2
1064	VECT1(4) = VECT2(4)**2
1065	TEMP = -1.D1VECT2(1) - 1.D1VECT2(2)
1066	VECT2(2) = 1.D1VECT2(1) - 1.D1VECT2(2)
1067	VECT2(1) = TEMP
1068	VECT2(3) = 1.D3*VECT2(3)
1069	VECT2(4) = 1.D-2*VECT2(4)
1070	SUM = 0.D0
1071	DO I = 1, 4
1072	SUM = SUM + VECT1(I) - VECT2(I)
1073	END DO
1074	DO I = 1, 4
1075	YP(I) = VECT2(I) - VECT1(I) + .5D0*SUM
1076	END DO
1077	GOTO 260
1078
1079	! PROBLEM E5
1080	200 XTEMP = -7.89D-10*Y(1)
1081	YP(1) = XTEMP - 1.1D7Y(1)Y(3)
1082	YP(2) = -XTEMP - 1.13D9Y(2)Y(3)
1083	YP(4) = 1.1D7Y(1)Y(3) - 1.13D3*Y(4)
1084	YP(3) = YP(2) - YP(4)
1085	GOTO 260
1086
1087	! PROBLEM CLASS F - CHEMICAL KINETICS EQUATIONS
1088
1089	! PROBLEM F1
1090	210 TEMP = 6.D-3*EXP(20.7D0-1.5D4/Y(1))
1091	YP(1) = 1.3D0(Y(3)-Y(1)) + 1.04D4TEMP*Y(2)
1092	YP(2) = 1.88D3(Y(4)-Y(2)(1.D0+TEMP))
1093	YP(3) = 1752.D0 - 269.D0Y(3) + 267.D0Y(1)
1094	YP(4) = .1D0 + 320.D0Y(2) - 321.D0Y(4)
1095	GOTO 260
1096
1097	! PROBLEM F2
1098	220 YP(1) = -Y(1) - Y(1)Y(2) + 294.D0Y(2)
1099	YP(2) = Y(1)(1.D0-Y(2))/98.D0 - 3.D0Y(2)
1100	GOTO 260
1101
1102	! PROBLEM F3
1103	230 YP(1) = -1.0D7Y(2)Y(1) + 1.D1*Y(3)
1104	YP(2) = -1.0D7Y(2)Y(1) - 1.D7Y(2)Y(5) + 1.D1Y(3) + 1.D1Y(4)
1105	YP(3) = 1.0D7Y(2)Y(1) - 1.001D4Y(3) + 1.D-3Y(4)
1106	YP(4) = 1.D4Y(3) - 1.0001D1Y(4) + 1.D7Y(2)Y(5)
1107	YP(5) = 1.D1Y(4) - 1.D7Y(2)*Y(5)
1108	GOTO 260
1109
1110	! PROBLEM F4
1111	240 S = 77.27D0
1112	T = 0.161D0
1113	Q = 8.375D-6
1114	F = 1.D0
1115	YP(1) = S(Y(2)-Y(1)Y(2)+Y(1)-QY(1)Y(1))
1116	YP(2) = (-Y(2)-Y(1)Y(2)+FY(3))/S
1117	YP(3) = T*(Y(1)-Y(3))
1118	GOTO 260
1119
1120	! PROBLEM F5
1121	250 YP(1) = -3.D11Y(1)Y(2) + 1.2D8Y(4) - 9.D11Y(1)*Y(3)
1122	YP(2) = -3.D11Y(1)Y(2) + 2.D7*Y(4)
1123	YP(3) = -9.D11Y(1)Y(3) + 1.D8*Y(4)
1124	YP(4) = 3.D11Y(1)Y(2) - 1.2D8Y(4) + 9.D11Y(1)*Y(3)
1125	260 CONTINUE
1126	IF (IWT<0) GOTO 270
1127	DO I = 1, N
1128	YP(I) = YP(I)/W(I)
1129	Y(I) = YTEMP(I)
1130	END DO
1131	270 CONTINUE
1132	RETURN
1133	END SUBROUTINE FCN
1134
1135	SUBROUTINE PDERV(X,Y)
1136
1137	! ROUTINE TO EVALUATE THE JACOBIAN MATRIX OF PARTIAL DERIVATIVES
1138	! CORRESPONDING TO THE DIFFERENTIAL EQUATION:
1139	! DY/DX = F(X,Y).
1140	! THE N*2 ELEMENTS OF THE ARRAY DY() ARE ASSIGNED THE VALUE OF
1141	! THE JACOBIAN MATRIX WITH ELEMENT I+(J-1)*N BEING ASSIGNED THE
1142	! VALUE OF DF(I)/DY(J). THE PARTICULAR EQUATION BEING INTEGRATED
1143	! IS INDICATED BY THE VALUE OF THE FLAG ID WHICH IS PASSED THROUGH
1144	! COMMON. IF A SCALED DIFFERENTIAL EQUATION IS BEING SOLVED (AS
1145	! SIGNALLED IWT) THE ELEMENTS OF THE JACOBIAN ARE SCALED ACCORDING-
1146	! LY BY THE WEIGHT VECTOR W(*).
1147
1148	IMPLICIT NONE
1149
1150	! .. Scalar Arguments ..
1151	DOUBLE PRECISION X
1152	! .. Array Arguments ..
1153	DOUBLE PRECISION Y(20)
1154	! .. Local Scalars ..
1155	DOUBLE PRECISION F, Q, S, SUM, T, TEMP, XTEMP1, XTEMP2, XTEMP3
1156	INTEGER I, ITMP, J, L
1157	! .. Local Arrays ..
1158	DOUBLE PRECISION BPARM(4), CPARM(4), VECT2(4), YTEMP(20)
1159	! .. Data statements ..
1160	DATA BPARM/3.D0, 8.D0, 25.D0, 1.D2/
1161	DATA CPARM/1.D-1, 1.D0, 1.D1, 2.D1/
1162
1163	! .. Executable Statements ..
1164
1165	NJAC = NJAC + 1
1166	IF (IWT<0) GOTO 10
1167	DO I = 1, N
1168	YTEMP(I) = Y(I)
1169	Y(I) = Y(I)*W(I)
1170	END DO
1171	10 CONTINUE
1172	GOTO (20,30,40,50,260,260,260,260,260,260,60,70,70,70,70,260,260,260, &
1173	260,260,80,90,90,90,90,260,260,260,260,260,100,110,120,130,140,150, &
1174	260,260,260,260,160,170,180,190,200,260,260,260,260,260,210,220,230, &
1175	240,250) ID
1176	GOTO 260
1177
1178	! PROBLEM CLASS A - LINEAR WITH REAL EIGENVALUES
1179
1180	! PROBLEM A1
1181	20 DO I = 1, 16
1182	DY(I) = 0.D0
1183	END DO
1184	DY(1) = -.5D0
1185	DY(6) = -1.D0
1186	DY(11) = -1.D2
1187	DY(16) = -9.D1
1188	GOTO 260
1189
1190	! PROBLEM A2
1191	30 DO I = 1, 81
1192	DY(I) = 0.D0
1193	END DO
1194	DO I = 2, 62, 10
1195	DY(I) = 1.D0
1196	DY(I+9) = -2.D0
1197	DY(I+18) = 1.D0
1198	END DO
1199	DY(1) = -1.8D3
1200	DY(10) = 9.D2
1201	DY(72) = 1.D3
1202	DY(81) = -2.D3
1203	GOTO 260
1204
1205	! PROBLEM A3
1206	40 DO I = 1, 16
1207	DY(I) = 0.D0
1208	END DO
1209	DY(1) = -1.D4
1210	DY(5) = 1.D2
1211	DY(6) = -1.D3
1212	DY(9) = -1.D1
1213	DY(10) = 1.D1
1214	DY(11) = -1.D0
1215	DY(13) = 1.D0
1216	DY(14) = -1.D1
1217	DY(15) = 1.D1
1218	DY(16) = -1.D-1
1219	GOTO 260
1220
1221	! PROBLEM A4
1222	50 DO I = 1, 100
1223	DY(I) = 0.D0
1224	END DO
1225	DO I = 1, 10
1226	DY((I-1)10+I) = -REAL(I)*5
1227	END DO
1228	GOTO 260
1229
1230	! PROBLEM CLASS B - LINEAR WITH NON-REAL EIGENVALUES
1231
1232	! PROBLEM B1
1233	60 DO I = 1, 16
1234	DY(I) = 0.D0
1235	END DO
1236	DY(1) = -1.D0
1237	DY(2) = -1.D2
1238	DY(5) = 1.D0
1239	DY(6) = -1.D0
1240	DY(11) = -1.D2
1241	DY(12) = -1.D4
1242	DY(15) = 1.D0
1243	DY(16) = -1.D2
1244	GOTO 260
1245
1246	! PROBLEMS B2, B3, B4, B5
1247	70 DO I = 1, 36
1248	DY(I) = 0.D0
1249	END DO
1250	DY(1) = -1.D1
1251	DY(2) = -BPARM(IID-1)
1252	DY(7) = BPARM(IID-1)
1253	DY(8) = -1.D1
1254	DY(15) = -4.D0
1255	DY(22) = -1.D0
1256	DY(29) = -.5D0
1257	DY(36) = -.1D0
1258	GOTO 260
1259
1260	! PROBLEM CLASS C - NON-LINEAR COUPLING FROM
1261	! STEADY STATE TO TRANSIENT
1262
1263	! PROBLEM C1
1264	80 DO I = 1, 16
1265	DY(I) = 0.D0
1266	END DO
1267	DY(1) = -1.D0
1268	DY(5) = 2.D0*Y(2)
1269	DY(6) = -1.D1
1270	DY(9) = 2.D0*Y(3)
1271	DY(10) = 2.D1*Y(3)
1272	DY(11) = -4.D1
1273	DY(13) = 2.D0*Y(4)
1274	DY(14) = 2.D1*Y(4)
1275	DY(15) = 8.D1*Y(4)
1276	DY(16) = -1.D2
1277	GOTO 260
1278
1279	! PROBLEMS C2, C3, C4, C5
1280	90 DO I = 1, 16
1281	DY(I) = 0.D0
1282	END DO
1283	DY(1) = -1.D0
1284	DY(2) = 2.D0Y(1)CPARM(IID-1)
1285	DY(3) = 8.D0Y(1)CPARM(IID-1)
1286	DY(4) = 2.D1Y(1)CPARM(IID-1)
1287	DY(6) = -1.D1
1288	DY(7) = 8.D0Y(2)CPARM(IID-1)
1289	DY(8) = 2.D1Y(2)CPARM(IID-1)
1290	DY(11) = -4.D1
1291	DY(12) = 2.D1Y(3)CPARM(IID-1)
1292	DY(16) = -1.D2
1293	GOTO 260
1294
1295	! PROBLEM CLASS D - NON-LINEAR WITH REAL EIGENVALUES
1296
1297	! PROBLEM D1
1298	100 DY(1) = -.2D0
1299	DY(2) = 1.D1
1300	DY(3) = 0.D0
1301	DY(4) = .2D0
1302	DY(5) = -6.D1 + .125D0*Y(3)
1303	DY(6) = 0.D0
1304	DY(7) = 0.D0
1305	DY(8) = .125D0*Y(2) + .125D0
1306	DY(9) = 0.D0
1307	GOTO 260
1308
1309	! PROBLEM D2
1310	110 DY(1) = -4.D-2
1311	DY(2) = 4.D2
1312	DY(3) = 0.D0
1313	DY(4) = 1.D-2*Y(3)
1314	DY(5) = -1.D2Y(3) - 6.D3Y(2)
1315	DY(6) = 6.D1*Y(2)
1316	DY(7) = .1D-1*Y(2)
1317	DY(8) = -1.D2*Y(2)
1318	DY(9) = 0.D0
1319	GOTO 260
1320
1321	! PROBLEM D3
1322	120 DY(1) = -1.D2*Y(2)
1323	DY(2) = DY(1)
1324	DY(3) = -DY(1)
1325	DY(4) = 0.D0
1326	DY(5) = -1.D2*Y(1)
1327	DY(7) = -DY(5)
1328	DY(8) = 2.D4*Y(2)
1329	DY(6) = DY(5) - DY(8)
1330	DY(6) = DY(6) - 2.D4*Y(2)
1331	DY(9) = 1.D0
1332	DY(10) = 1.D0
1333	DY(11) = -1.D0
1334	DY(12) = 0.D0
1335	DY(13) = 0.D0
1336	DY(14) = 2.D0
1337	DY(15) = 0.D0
1338	DY(16) = -1.D0
1339	GOTO 260
1340
1341	! PROBLEM D4
1342	130 DY(1) = -.013D0 - 1.D3*Y(3)
1343	DY(2) = 0.D0
1344	DY(4) = 0.D0
1345	DY(5) = -2.5D3*Y(3)
1346	DY(7) = -1.D3*Y(1)
1347	DY(8) = -2.5D3*Y(2)
1348	DO I = 3, 9, 3
1349	DY(I) = DY(I-1) + DY(I-2)
1350	END DO
1351	GOTO 260
1352
1353	! PROBLEM D5
1354	140 XTEMP1 = Y(1) + 1.D3
1355	XTEMP2 = Y(1) + 1.D0
1356	XTEMP3 = .01D0 + Y(1) + Y(2)
1357	DY(2) = -(1.D0+Y(2)**2)
1358	DY(3) = -(1.D0+XTEMP1*XTEMP2)
1359	DY(1) = -(-DY(3)+XTEMP3*(XTEMP1+XTEMP2))
1360	DY(4) = -(2.D0XTEMP3Y(2)-DY(2))
1361	GOTO 260
1362
1363	! PROBLEM D6
1364	150 DY(1) = -1.D0 - 1.D8*Y(3)
1365	DY(2) = 0.D0
1366	DY(4) = 0.D0
1367	DY(5) = -1.D1 - 3.D7*Y(3)
1368	DY(7) = 1.D8*(1.D0-Y(1))
1369	DY(8) = 3.D7*(1.D0-Y(2))
1370	DO I = 3, 9, 3
1371	DY(I) = -DY(I-2) - DY(I-1)
1372	END DO
1373	GOTO 260
1374
1375	! PROBLEM CLASS E - NON-LINEAR WITH NON-REAL EIGENVALUES
1376
1377	! PROBLEM E1
1378	160 DO I = 1, 16
1379	DY(I) = 0.D0
1380	END DO
1381	DY(5) = 1.D0
1382	DY(10) = 1.D0
1383	DY(15) = 1.D0
1384	XTEMP1 = Y(1)
1385	XTEMP2 = Y(2)/(XTEMP12+1.D0)2
1386	DY(4) = 3.D0XTEMP12 - XTEMP1COS(XTEMP1) - SIN(XTEMP1) - 1.D8 - &
1387	2.D0XTEMP1Y(2)Y(3)XTEMP2
1388	DY(8) = 2.D0Y(3)Y(2)/(1.D0+Y(1)**2) - 4.D6
1389	DY(12) = Y(2)Y(2)/(1.D0+Y(1)*2) + 1.D0 - 6.D4
1390	DY(16) = 1.D1EXP(-Y(4)2)(1.D0-2.D0Y(4)*2) - 4.D2
1391	GOTO 260
1392
1393	! PROBLEM E2
1394	170 DY(1) = 0.D0
1395	DY(2) = -1.D1Y(1)Y(2) - 1.D0
1396	DY(3) = 1.D0
1397	DY(4) = 5.D0 - 5.D0Y(1)Y(1)
1398	GOTO 260
1399
1400	! PROBLEM E3
1401	180 DY(1) = -55.D0 - Y(3)
1402	DY(2) = .785D-1
1403	DY(3) = 0.1D0
1404	DY(4) = 65.D0
1405	DY(5) = -.785D-1
1406	DY(6) = 0.D0
1407	DY(7) = -Y(1)
1408	DY(8) = 0.D0
1409	DY(9) = 0.D0
1410	GOTO 260
1411
1412	! PROBLEM E4
1413	190 SUM = Y(1) + Y(2) + Y(3) + Y(4)
1414	DO I = 1, 4
1415	VECT2(I) = -Y(I) + .5D0*SUM
1416	END DO
1417	DO I = 1, 16
1418	DY(I) = 0.D0
1419	END DO
1420	DY(1) = VECT2(1) + 1.D1
1421	DY(2) = VECT2(2) - 1.D1
1422	DY(5) = -DY(2)
1423	DY(6) = DY(1)
1424	DY(11) = 2.D0*VECT2(3) - 1.D3
1425	DY(16) = 2.D0*VECT2(4) - 1.D-2
1426	DO I = 1, 4
1427	SUM = 0.D0
1428	DO J = 1, 4
1429	L = I + (J-1)*4
1430	SUM = SUM + DY(L)
1431	END DO
1432	DO J = 1, 4
1433	L = I + (J-1)*4
1434	DY(L) = -DY(L) + .5D0*SUM
1435	END DO
1436	END DO
1437	DO J = 1, 4
1438	SUM = 0.D0
1439	DO I = 1, 4
1440	L = I + (J-1)*4
1441	SUM = SUM + DY(L)
1442	END DO
1443	DO I = 1, 4
1444	L = I + (J-1)*4
1445	DY(L) = -DY(L) + .5D0*SUM
1446	END DO
1447	END DO
1448	GOTO 260
1449
1450	! PROBLEM E5
1451	200 DY(1) = -7.89D-10 - 1.1D7*Y(3)
1452	DY(2) = 7.89D-10
1453	DY(4) = 1.1D7*Y(3)
1454	DY(5) = 0.D0
1455	DY(6) = -1.13D9*Y(3)
1456	DY(8) = 0.D0
1457	DY(9) = -1.1D7*Y(1)
1458	DY(10) = -1.13D9*Y(2)
1459	DY(12) = -DY(9)
1460	DY(13) = 0.D0
1461	DY(14) = 0.D0
1462	DY(16) = -1.13D3
1463	DO I = 3, 15, 4
1464	DY(I) = DY(I-1) - DY(I+1)
1465	END DO
1466	GOTO 260
1467
1468	! PROBLEM CLASS F - CHEMICAL KINETICS EQUATIONS
1469
1470	! PROBLEM F1
1471	210 TEMP = 90.D0EXP(20.7D0-1.5D4/Y(1))/Y(1)*2
1472	DY(1) = -1.3D0 + 1.04D4TEMPY(2)
1473	DY(2) = -1.88D3Y(2)TEMP
1474	DY(3) = 267.D0
1475	DY(4) = 0.D0
1476	TEMP = 6.D-3*EXP(20.7D0-1.5D4/Y(1))
1477	DY(5) = 1.04D4*TEMP
1478	DY(6) = -1.88D3*(1.D0+TEMP)
1479	DY(7) = 0.D0
1480	DY(8) = 320.D0
1481	DY(9) = 1.3D0
1482	DY(10) = 0.D0
1483	DY(11) = -269.D0
1484	DY(12) = 0.0D0
1485	DY(13) = 0.0D0
1486	DY(14) = 1.88D3
1487	DY(15) = 0.0D0
1488	DY(16) = -321.0D0
1489	GOTO 260
1490
1491	! PROBLEM F2
1492	220 DY(1) = -1.D0 - Y(2)
1493	DY(2) = (1.D0-Y(2))/98.D0
1494	DY(3) = -Y(1) + 294.D0
1495	DY(4) = -Y(1)/98.D0 - 3.D0
1496	GOTO 260
1497
1498	! PROBLEM F3
1499	230 DY(1) = -1.D7*Y(2)
1500	DY(2) = -1.D7*Y(2)
1501	DY(3) = 1.D7*Y(2)
1502	DY(4) = 0.0D0
1503	DY(5) = 0.0D0
1504	DY(6) = -1.D7*Y(1)
1505	DY(7) = -1.D7Y(1) - 1.D7Y(5)
1506	DY(8) = 1.D7*Y(1)
1507	DY(9) = 1.D7*Y(5)
1508	DY(10) = -1.D7*Y(5)
1509	DY(11) = 1.D1
1510	DY(12) = 1.D1
1511	DY(13) = -1.001D4
1512	DY(14) = 1.D4
1513	DY(15) = 0.0D0
1514	DY(16) = 0.0D0
1515	DY(17) = 1.D1
1516	DY(18) = 1.D-3
1517	DY(19) = -1.0001D1
1518	DY(20) = 1.D1
1519	DY(21) = 0.0D0
1520	DY(22) = -1.D7*Y(2)
1521	DY(23) = 0.0D0
1522	DY(24) = 1.D7*Y(2)
1523	DY(25) = -1.0D7*Y(2)
1524	GOTO 260
1525
1526	! PROBLEM F4
1527	240 S = 77.27D0
1528	T = 0.161D0
1529	Q = 8.375D-6
1530	F = 1.D0
1531	DY(1) = S(-Y(2)+1.D0-2.D0Q*Y(1))
1532	DY(2) = -Y(2)/S
1533	DY(3) = T
1534	DY(4) = S*(1.D0-Y(1))
1535	DY(5) = (-1.D0-Y(1))/S
1536	DY(6) = 0.D0
1537	DY(7) = 0.D0
1538	DY(8) = F/S
1539	DY(9) = -T
1540	GOTO 260
1541
1542	! PROBLEM F5
1543	250 DY(1) = -3.D11Y(2) - 9.D11Y(3)
1544	DY(2) = -3.D11*Y(2)
1545	DY(3) = -9.D11*Y(3)
1546	DY(4) = 3.D11Y(2) + 9.D11Y(3)
1547	DY(5) = -3.D11*Y(1)
1548	DY(6) = -3.D11*Y(1)
1549	DY(7) = 0.0D0
1550	DY(8) = 3.D11*Y(1)
1551	DY(9) = -9.D11*Y(1)
1552	DY(10) = 0.0D0
1553	DY(11) = -9.D11*Y(1)
1554	DY(12) = 9.D11*Y(1)
1555	DY(13) = 1.2D8
1556	DY(14) = 2.D7
1557	DY(15) = 1.D8
1558	DY(16) = -1.2D8
1559	260 CONTINUE
1560	IF (IWT<0) GOTO 270
1561	DO I = 1, N
1562	Y(I) = YTEMP(I)
1563	DO J = 1, N
1564	ITMP = I + (J-1)*N
1565	DY(ITMP) = DY(ITMP)*W(J)/W(I)
1566	END DO
1567	END DO
1568	270 CONTINUE
1569	RETURN
1570	END SUBROUTINE PDERV
1571
1572	END MODULE STIFFSET
1573
1574	!******************************************************************
1575
1576	PROGRAM DEMOSTIFF
1577
1578	USE STIFFSET
1579	USE DVODE_F90_M
1580
1581	IMPLICIT NONE
1582	INTEGER ITASK, ISTATE, ISTATS, NEQ, I, CLASS, PROBLEM, MYID, ITEST, ISTR, &
1583	IJAC, JTYPE, CONSTANTJ, ITOL, IADIM, IA, JADIM, JA, ROW, COL, ML, MU, &
1584	IJACSP , NUM_S, NUM_J, NUM_D, Total_Solutions, ISCALE, ITIME, COMPS, &
1585	METHOD, WHICH_PROBS, WHICH_TOLS, COUNTS
1586	DOUBLE PRECISION RSTATS, T, TOUT, HBEGIN, HBOUND, TBEGIN, TEND, Y, EPS, &
1587	YINIT, YFINAL, RELERR_TOLERANCES, ABSERR_TOLERANCES, AERROR, ERRMAX, &
1588	ERSTATS, LBOUNDS, UBOUNDS, ERSTATS2
1589	REAL DVTIME, DVTIME1, DVTIME2, EXECUTION_TIMES
1590	DIMENSION Y(20), RSTATS(22), ISTATS(31), YINIT(20), YFINAL(20), MYID(55)
1591	DIMENSION RELERR_TOLERANCES(20), ABSERR_TOLERANCES(20), AERROR(20), &
1592	IA(21), JA(400), ERSTATS(12,55,3), NUM_S(12,55,3), NUM_J(12,55,3), &
1593	NUM_D(12,55,3), EXECUTION_TIMES(12), COMPS(20), LBOUNDS(20), &
1594	UBOUNDS(20), ERSTATS2(2,12,55,6), WHICH_PROBS(55), WHICH_TOLS(12), &
1595	COUNTS(2,12,55,6,3)
1596	LOGICAL J_IS_CONSTANT, ANALYTIC_JACOBIAN, ERRORS, SUPPLY_STRUCTURE, &
1597	TOLVEC, USE_JACSP, BOUNDS, USEW, USEHBEGIN
1598	INTRINSIC ABS, MAX, MAXVAL, EPSILON
1599	TYPE (VODE_OPTS) :: OPTIONS
1600	DATA MYID/1, 2, 3, 4, 0, 0, 0, 0, 0, 0, 11, 12, 13, 14, 15, 0, 0, 0, 0, &
1601	0, 21, 22, 23, 24, 25, 0, 0, 0, 0, 0, 31, 32, 33, 34, 35, 36, 0, 0, 0, &
1602	0, 41, 42, 43, 44, 45, 0, 0, 0, 0, 0, 51, 52, 53, 54, 55/
1603
1604	OPEN (UNIT=6,FILE='stiffoptions.dat')
1605
1606	! Initialize the cumulative solutions total.
1607	Total_Solutions = 0
1608
1609	! Use vector tolerances (same solution in either case)?
1610	TOLVEC = .FALSE.
1611
1612	! Initialize the flag to indicate whether any errors occurred.
1613	ERRORS = .FALSE.
1614
1615	! Execution times per tolerance.
1616	EXECUTION_TIMES(1:12) = 0.0E0
1617	ERSTATS2(1:2,1:12,1:55,1:6) = 0.0D0
1618	WHICH_PROBS(1:55) = 0
1619	WHICH_TOLS(1:12) = 0
1620	COUNTS(1:2,1:12,1:55,1:6,1:3) = 0
1621
1622	WRITE(6,90032)
1623
1624	! Enter the scale equations loop.
1625	! 1 = the ODEs will be scaled
1626	! 2 = the ODEs will not be scaled
1627	DO ISCALE = 1 , 2
1628	USEW = .TRUE.
1629	IF (ISCALE == 2) USEW = .FALSE.
1630
1631	! Enter the numerical Jacobian formation loop.
1632	! 1 = use Doug's JACSP for Jacobian
1633	! 2 = use original VODE Jacobian algorithm
1634	DO IJACSP = 1, 2
1635	USE_JACSP = .TRUE.
1636	IF (IJACSP == 2) USE_JACSP = .FALSE.
1637
1638	! Initialize the max error array for this value of IJACSP.
1639	ERSTATS(1:12,1:15,1:3) = 0.0D0
1640
1641	! Initialize the stats arrays.
1642	NUM_S(1:12,1:15,1:3) = 0
1643	NUM_J(1:12,1:15,1:3) = 0
1644	NUM_D(1:12,1:15,1:3) = 0
1645
1646	! Enter the sparsity structure loop.
1647	! 1 = numerically determined sparse pointer arrays
1648	! 2 = supplied pointer arrays
1649	! Make this a one-trip loop (1 to 1 or 2 to 2) for stats to be meaningful:
1650	DO ISTR = 2, 2
1651	SUPPLY_STRUCTURE = .FALSE.
1652	IF (ISTR == 2) SUPPLY_STRUCTURE = .TRUE.
1653
1654	! Enter the error tolerance loop.
1655	! Error tolerance = 10^(-ITOL)
1656	DO ITOL = 5, 12, 1
1657
1658	WHICH_TOLS(ITOL) = 1
1659
1660	! Enter the linear algebra type loop.
1661	! 1 = dense Jacobian
1662	! 2 = sparse Jacobian
1663	! 3 = banded Jacobian
1664	DO JTYPE = 1, 3
1665
1666	! Enter the constant Jacobian loop.
1667	! 1 = Jacobian is not constant
1668	! 2 = Jacobian is constant for classes 0 and 1
1669	! Make this a one-trip loop (1 to 1 or 2 to 2) for stats to be meaningful:
1670	DO CONSTANTJ = 1, 1
1671
1672	! Enter the numerical or analytical Jacobian loop.
1673	! 1 = numerical Jacobian
1674	! 2 = analytical Jacobian
1675	! Make this a one-trip loop (1 to 1 or 2 to 2) for stats to be meaningful:
1676	DO IJAC = 1, 1
1677	ANALYTIC_JACOBIAN = .TRUE.
1678	IF (IJAC == 1) ANALYTIC_JACOBIAN = .FALSE.
1679
1680	IF (JTYPE==1 .AND. IJACSP==1) METHOD = 1
1681	IF (JTYPE==2 .AND. IJACSP==1) METHOD = 2
1682	IF (JTYPE==3 .AND. IJACSP==1) METHOD = 3
1683	IF (JTYPE==1 .AND. IJACSP==2) METHOD = 4
1684	IF (JTYPE==2 .AND. IJACSP==2) METHOD = 5
1685	IF (JTYPE==3 .AND. IJACSP==2) METHOD = 6
1686
1687	! Enter the problem test loop.
1688	DO ITEST = 1, 55
1689
1690	! JACS supplies the full matrix in the analytic Jacobian case.
1691	IF (IJAC == 2 .AND. ISTR == 1) GOTO 20
1692	ID = MYID(ITEST)
1693	IF (ID == 0) GOTO 20
1694	WHICH_PROBS(ITEST) = 1
1695	IID = MOD(ID,10)
1696	WRITE (6,90010)
1697	CLASS = ID/10
1698	PROBLEM = ID - 10*CLASS
1699	J_IS_CONSTANT = .FALSE.
1700	IF ((CLASS==0 .OR. CLASS==1) .AND. CONSTANTJ==2) J_IS_CONSTANT = .TRUE.
1701
1702	! Output header.
1703	IF (CLASS == 0) THEN
1704	WRITE (6,90000) PROBLEM
1705	ELSE IF (CLASS == 1) THEN
1706	WRITE (6,90001) PROBLEM
1707	ELSE IF (CLASS == 2) THEN
1708	WRITE (6,90002) PROBLEM
1709	ELSE IF (CLASS == 3) THEN
1710	WRITE (6,90003) PROBLEM
1711	ELSE IF (CLASS == 4) THEN
1712	WRITE (6,90004) PROBLEM
1713	ELSE IF (CLASS == 5) THEN
1714	WRITE (6,90005) PROBLEM
1715	END IF
1716	WRITE(6,*) ' Results for ITOL = ', ITOL, ' follow.'
1717	PRINT *, ' Results for ITOL = ', ITOL, ' follow.'
1718	IF (IJACSP == 1) THEN
1719	WRITE(6,*) ' Results for JACSP Jacobian follow.'
1720	PRINT *, ' Results for JACSP Jacobian follow.'
1721	ELSE
1722	WRITE(6,*) ' Results for VODE Jacobian follow.'
1723	PRINT *, ' Results for VODE Jacobian follow.'
1724	END IF
1725	IF (ISCALE == 1) THEN
1726	WRITE(6,*) ' The ODEs will be scaled.'
1727	PRINT *, ' The ODEs will be scaled.'
1728	ELSE
1729	WRITE(6,*) ' The ODEs will not be scaled.'
1730	PRINT *, ' The ODEs will not be scaled.'
1731	END IF
1732	IF (ISTR == 1) THEN
1733	WRITE(6,*) ' Results for numerically determined sparse pointers follow.'
1734	PRINT *, ' Results for numerically determined sparse pointers follow.'
1735	ELSE
1736	WRITE(6,*) ' Results for user supplied sparse pointers follow.'
1737	PRINT *, ' Results for user supplied sparse pointers follow.'
1738	END IF
1739	IF (JTYPE == 1) THEN
1740	WRITE(6,*) ' Results for dense Jacobian option follow.'
1741	PRINT *, ' Results for dense Jacobian option follow.'
1742	END IF
1743	IF (JTYPE == 2) THEN
1744	WRITE(6,*) ' Results for sparse Jacobian option follow.'
1745	PRINT *, ' Results for sparse Jacobian option follow.'
1746	END IF
1747	IF (JTYPE == 3) THEN
1748	WRITE(6,*) ' Results for banded Jacobian option follow.'
1749	PRINT *, ' Results for banded Jacobian option follow.'
1750	END IF
1751	IF (CONSTANTJ == 1) THEN
1752	WRITE(6,*) ' Results for non-constant Jacobian option follow.'
1753	PRINT *, ' Results for non-constant Jacobian option follow.'
1754	ELSE
1755	WRITE(6,*) ' Results for constant Jacobian option follow.'
1756	PRINT *, ' Results for constant Jacobian option follow.'
1757	END IF
1758	IF (IJAC == 1) THEN
1759	WRITE(6,*) ' Results for numerical Jacobian option follow.'
1760	PRINT *, ' Results for numerical Jacobian option follow.'
1761	ELSE
1762	WRITE(6,*) ' Results for analytical Jacobian option follow.'
1763	PRINT *, ' Results for analytical Jacobian option follow.'
1764	END IF
1765
1766	! Initialize the problem.
1767	! Scale the ODEs?
1768	! USEW = .TRUE.
1769	IWT = -1
1770	IF (USEW) IWT = 1
1771	! Get the problem information.
1772	CALL IVALU(TBEGIN,TEND,HBEGIN,HBOUND,YINIT)
1773	! Use the IVALU starting step size?
1774	USEHBEGIN = .TRUE.
1775	IF (.NOT. USEHBEGIN) HBEGIN = 0.0D0
1776	! Define the number of ODEs.
1777	NEQ = N
1778	! Use the full matrix for the banded solution.
1779	ML = NEQ - 1
1780	MU = NEQ - 1
1781	! Initial and final integration times.
1782	T = TBEGIN
1783	TOUT = TEND
1784	! Initial solution.
1785	Y(1:NEQ) = YINIT(1:NEQ)
1786	! Error tolerances.
1787	EPS = 1.0D0 / 10.0D0**ITOL
1788	RELERR_TOLERANCES(1:NEQ) = EPS
1789	ABSERR_TOLERANCES(1:NEQ) = EPS
1790	WRITE (6,90007) ID,TBEGIN,TEND,HBEGIN,HBOUND,IWT,N,EPS,Y(1:NEQ)
1791	BOUNDS = .FALSE.
1792	! Force nonnegativity for the chemical kinetics problems in Class F.
1793	IF (ITEST >= 51) THEN
1794	BOUNDS = .TRUE.
1795	COMPS(1) = 1
1796	COMPS(2) = 2
1797	COMPS(3) = 3
1798	DO I = 1, NEQ
1799	COMPS(I) = I
1800	END DO
1801	LBOUNDS(1:NEQ) = 0.0D0
1802	UBOUNDS(1:NEQ) = 1.0D50
1803	END IF
1804	IF (BOUNDS) WRITE(6,90040)
1805	! Initialize the integration flags.
1806	ITASK = 1
1807	ISTATE = 1
1808
1809	! Use the full matrix for sparsity structure.
1810	IF (JTYPE == 2 .AND. SUPPLY_STRUCTURE) THEN
1811	IADIM = NEQ + 1
1812	JADIM = NEQ * NEQ
1813	IA(1) = 1
1814	DO I = 1, NEQ
1815	IA(I+1) = IA(I) + NEQ
1816	END DO
1817	I = 0
1818	DO COL = 1, NEQ
1819	I = NEQ*(COL-1)
1820	DO ROW = 1, NEQ
1821	I = I + 1
1822	JA(I) = ROW
1823	END DO
1824	END DO
1825	END IF
1826
1827	CALL CPU_TIME(DVTIME1)
1828
1829	! Set the integration options.
1830	IF (JTYPE == 1) THEN
1831	! Dense solution ...
1832	IF (TOLVEC) THEN
1833	! Supply vectors of tolerances.
1834	IF (BOUNDS) THEN
1835	OPTIONS = SET_OPTS(DENSE_J=.TRUE., &
1836	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1837	RELERR_VECTOR=RELERR_TOLERANCES(1:NEQ), &
1838	ABSERR_VECTOR=ABSERR_TOLERANCES(1:NEQ), &
1839	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1840	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1841	JACOBIAN_BY_JACSP=USE_JACSP, &
1842	CONSTRAINED=COMPS(1:NEQ), &
1843	CLOWER=LBOUNDS(1:NEQ),CUPPER=UBOUNDS(1:NEQ))
1844	ELSE
1845	OPTIONS = SET_OPTS(DENSE_J=.TRUE., &
1846	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1847	RELERR_VECTOR=RELERR_TOLERANCES(1:NEQ), &
1848	ABSERR_VECTOR=ABSERR_TOLERANCES(1:NEQ), &
1849	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1850	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1851	JACOBIAN_BY_JACSP=USE_JACSP)
1852	END IF
1853	ELSE
1854	! Supply scalar tolerances.
1855	IF (BOUNDS) THEN
1856	OPTIONS = SET_OPTS(DENSE_J=.TRUE., &
1857	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1858	RELERR=EPS,ABSERR=EPS, &
1859	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1860	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1861	JACOBIAN_BY_JACSP=USE_JACSP, &
1862	CONSTRAINED=COMPS(1:NEQ), &
1863	CLOWER=LBOUNDS(1:NEQ),CUPPER=UBOUNDS(1:NEQ))
1864	ELSE
1865	OPTIONS = SET_OPTS(DENSE_J=.TRUE., &
1866	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1867	RELERR=EPS,ABSERR=EPS, &
1868	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1869	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1870	JACOBIAN_BY_JACSP=USE_JACSP)
1871	END IF
1872	END IF
1873	END IF
1874
1875	IF (JTYPE == 2) THEN
1876	! Sparse solution ...
1877	IF (TOLVEC) THEN
1878	! Supply vectors of tolerances.
1879	IF (BOUNDS) THEN
1880	OPTIONS = SET_OPTS(SPARSE_J=.TRUE., &
1881	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1882	RELERR_VECTOR=RELERR_TOLERANCES(1:NEQ), &
1883	ABSERR_VECTOR=ABSERR_TOLERANCES(1:NEQ), &
1884	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1885	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1886	USER_SUPPLIED_SPARSITY=SUPPLY_STRUCTURE, &
1887	JACOBIAN_BY_JACSP=USE_JACSP, &
1888	MA28_RPS=.TRUE.,CONSTRAINED=COMPS(1:NEQ), &
1889	CLOWER=LBOUNDS(1:NEQ),CUPPER=UBOUNDS(1:NEQ))
1890	ELSE
1891	OPTIONS = SET_OPTS(SPARSE_J=.TRUE., &
1892	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1893	RELERR_VECTOR=RELERR_TOLERANCES(1:NEQ), &
1894	ABSERR_VECTOR=ABSERR_TOLERANCES(1:NEQ), &
1895	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1896	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1897	USER_SUPPLIED_SPARSITY=SUPPLY_STRUCTURE, &
1898	JACOBIAN_BY_JACSP=USE_JACSP, &
1899	MA28_RPS=.TRUE.)
1900	END IF
1901	ELSE
1902	! Supply scalar tolerances.
1903	IF (BOUNDS) THEN
1904	OPTIONS = SET_OPTS(SPARSE_J=.TRUE., &
1905	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1906	RELERR=EPS,ABSERR=EPS, &
1907	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1908	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1909	USER_SUPPLIED_SPARSITY=SUPPLY_STRUCTURE, &
1910	JACOBIAN_BY_JACSP=USE_JACSP, &
1911	MA28_RPS=.TRUE.,CONSTRAINED=COMPS(1:NEQ), &
1912	CLOWER=LBOUNDS(1:NEQ),CUPPER=UBOUNDS(1:NEQ))
1913	ELSE
1914	OPTIONS = SET_OPTS(SPARSE_J=.TRUE., &
1915	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1916	RELERR=EPS,ABSERR=EPS, &
1917	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1918	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1919	USER_SUPPLIED_SPARSITY=SUPPLY_STRUCTURE, &
1920	JACOBIAN_BY_JACSP=USE_JACSP, &
1921	MA28_RPS=.TRUE.)
1922	END IF
1923	END IF
1924	END IF
1925
1926	IF (JTYPE == 3) THEN
1927	! Banded solution ...
1928	IF (TOLVEC) THEN
1929	! Supply vectors of tolerances.
1930	IF (BOUNDS) THEN
1931	OPTIONS = SET_OPTS(BANDED_J=.TRUE., &
1932	LOWER_BANDWIDTH=ML,UPPER_BANDWIDTH=MU, &
1933	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1934	RELERR_VECTOR=RELERR_TOLERANCES(1:NEQ), &
1935	ABSERR_VECTOR=ABSERR_TOLERANCES(1:NEQ), &
1936	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1937	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1938	JACOBIAN_BY_JACSP=USE_JACSP, &
1939	CONSTRAINED=COMPS(1:NEQ), &
1940	CLOWER=LBOUNDS(1:NEQ),CUPPER=UBOUNDS(1:NEQ))
1941	ELSE
1942	OPTIONS = SET_OPTS(BANDED_J=.TRUE., &
1943	LOWER_BANDWIDTH=ML,UPPER_BANDWIDTH=MU, &
1944	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1945	RELERR_VECTOR=RELERR_TOLERANCES(1:NEQ), &
1946	ABSERR_VECTOR=ABSERR_TOLERANCES(1:NEQ), &
1947	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1948	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1949	JACOBIAN_BY_JACSP=USE_JACSP)
1950	END IF
1951	ELSE
1952	! Supply scalar tolerances.
1953	IF (BOUNDS) THEN
1954	OPTIONS = SET_OPTS(BANDED_J=.TRUE., &
1955	LOWER_BANDWIDTH=ML,UPPER_BANDWIDTH=MU, &
1956	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1957	RELERR=EPS,ABSERR=EPS, &
1958	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1959	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1960	JACOBIAN_BY_JACSP=USE_JACSP, &
1961	CONSTRAINED=COMPS(1:NEQ), &
1962	CLOWER=LBOUNDS(1:NEQ),CUPPER=UBOUNDS(1:NEQ))
1963	ELSE
1964	OPTIONS = SET_OPTS(BANDED_J=.TRUE., &
1965	LOWER_BANDWIDTH=ML,UPPER_BANDWIDTH=MU, &
1966	USER_SUPPLIED_JACOBIAN=ANALYTIC_JACOBIAN, &
1967	RELERR=EPS,ABSERR=EPS, &
1968	MXSTEP=100000,H0=HBEGIN,HMAX=HBOUND, &
1969	CONSTANT_JACOBIAN=J_IS_CONSTANT, &
1970	JACOBIAN_BY_JACSP=USE_JACSP)
1971	END IF
1972	END IF
1973	END IF
1974
1975	! Supply the sparse structure arrays directly.
1976	IF (JTYPE==2 .AND. SUPPLY_STRUCTURE) THEN
1977	CALL USERSETS_IAJA(IA(1:IADIM),IADIM,JA(1:JADIM),JADIM)
1978	END IF
1979
1980	! Perform the integration.
1981	IF (JTYPE == 1) THEN
1982	CALL DVODE_F90(DERIVS,NEQ,Y,T,TOUT,ITASK,ISTATE,OPTIONS,J_FCN=JACD)
1983	END IF
1984	IF (JTYPE == 2) THEN
1985	CALL DVODE_F90(DERIVS,NEQ,Y,T,TOUT,ITASK,ISTATE,OPTIONS,J_FCN=JACS)
1986	END IF
1987	IF (JTYPE == 3) THEN
1988	CALL DVODE_F90(DERIVS,NEQ,Y,T,TOUT,ITASK,ISTATE,OPTIONS,J_FCN=JACB)
1989	END IF
1990
1991	CALL CPU_TIME(DVTIME2)
1992	DVTIME = DVTIME2 - DVTIME1
1993	EXECUTION_TIMES(ITOL) = EXECUTION_TIMES(ITOL) + DVTIME
1994
1995	Total_Solutions = Total_Solutions + 1
1996
1997	! Check if an error occurred.
1998	IF (ISTATE < 0) THEN
1999	WRITE (6,90006) ISTATE
2000	ERRORS = .TRUE.
2001	END IF
2002
2003	! Gather the integration statistics.
2004	CALL GET_STATS(RSTATS,ISTATS)
2005	WRITE (6,90009) ISTATS(11), ISTATS(12), ISTATS(13)
2006	NUM_S(ITOL,ITEST,JTYPE) = ISTATS(11)
2007	NUM_D(ITOL,ITEST,JTYPE) = ISTATS(12)
2008	NUM_J(ITOL,ITEST,JTYPE) = ISTATS(13)
2009
2010	! Calculate the error in the final solution.
2011	CALL EVALU(YFINAL)
2012	DO I = 1, NEQ
2013	AERROR(I) = ABS(Y(I)-YFINAL(I))
2014	END DO
2015	ERRMAX = MAXVAL(AERROR(1:NEQ))
2016	ERSTATS(ITOL,ITEST,JTYPE) = ERRMAX
2017	ERSTATS2(ISCALE,ITOL,ITEST,METHOD) = ERRMAX
2018	COUNTS(ISCALE,ITOL,ITEST,METHOD,1) = ISTATS(11)
2019	COUNTS(ISCALE,ITOL,ITEST,METHOD,2) = ISTATS(12)
2020	COUNTS(ISCALE,ITOL,ITEST,METHOD,3) = ISTATS(13)
2021	WRITE (6,90008) (I,Y(I),YFINAL(I),AERROR(I),I=1,NEQ)
2022
2023	! Release the work arrays and determine how much storage was required.
2024	CALL RELEASE_ARRAYS
2025
2026	20 CONTINUE
2027	END DO ! End of ITEST Loop
2028	END DO ! End of IJAC Loop
2029	END DO ! End of JTYPE Loop
2030	END DO ! End of CONSTANTJ Loop
2031	END DO ! End of ITOL Loop
2032	END DO ! End of ISTR Loop
2033
2034	! Print the maximum errors for this value of IJACSP.
2035	DO ITOL = 5, 12, 1
2036	WRITE(6,90016) ITOL
2037	WRITE(6,90020)
2038	IF (IJACSP == 1) WRITE(6,90023)
2039	IF (IJACSP == 2) WRITE(6,90022)
2040	IF (ISCALE == 1) WRITE(6,90030)
2041	IF (ISCALE == 2) WRITE(6,90031)
2042	WRITE(6,90021)
2043	WRITE(6,90015)
2044	DO ITEST = 1, 55
2045	IF (WHICH_PROBS(ITEST) == 1) THEN
2046	ID = MYID(ITEST)
2047	IF (ID /= 0) WRITE(6,90014) ITOL, ITEST, &
2048	(ERSTATS(ITOL,ITEST,JTYPE),JTYPE=1,3)
2049	END IF
2050	END DO
2051	END DO
2052
2053	! Print the integration stats for this value of IJACSP.
2054	DO ITOL = 5, 12, 1
2055	WRITE(6,90016) ITOL
2056	WRITE(6,90024)
2057	IF (IJACSP == 1) WRITE(6,90023)
2058	IF (IJACSP == 2) WRITE(6,90022)
2059	IF (ISCALE == 1) WRITE(6,90030)
2060	IF (ISCALE == 2) WRITE(6,90031)
2061	WRITE(6,90029)
2062	DO ITEST = 1, 55
2063	IF (WHICH_PROBS(ITEST) == 1) THEN
2064	ID = MYID(ITEST)
2065	IF (ID /= 0) THEN
2066	WRITE(6,90026) ITEST, (NUM_S(ITOL,ITEST,JTYPE),JTYPE=1,3)
2067	WRITE(6,90027) (NUM_J(ITOL,ITEST,JTYPE),JTYPE=1,3)
2068	WRITE(6,90028) (NUM_D(ITOL,ITEST,JTYPE),JTYPE=1,3)
2069	WRITE(6,*) ' '
2070	END IF
2071	END IF
2072	END DO
2073	END DO
2074
2075	END DO ! End of IJACSP Loop
2076	END DO ! End of ISCALE Loop
2077
2078	WRITE(6,90045)
2079
2080	DO ITEST = 1, 55
2081	IF (WHICH_PROBS(ITEST) == 1) THEN
2082	ID = MYID(ITEST)
2083	IID = MOD(ID,10)
2084	WRITE (6,90010)
2085	CLASS = ID/10
2086	PROBLEM = ID - 10*CLASS
2087	IF (CLASS == 0) THEN
2088	WRITE (6,90000) PROBLEM
2089	ELSE IF (CLASS == 1) THEN
2090	WRITE (6,90001) PROBLEM
2091	ELSE IF (CLASS == 2) THEN
2092	WRITE (6,90002) PROBLEM
2093	ELSE IF (CLASS == 3) THEN
2094	WRITE (6,90003) PROBLEM
2095	ELSE IF (CLASS == 4) THEN
2096	WRITE (6,90004) PROBLEM
2097	ELSE IF (CLASS == 5) THEN
2098	WRITE (6,90005) PROBLEM
2099	END IF
2100	DO ITOL = 5, 12, 1
2101	IF (WHICH_TOLS(ITOL) == 1) THEN
2102	DO ISCALE = 1, 2
2103	IF (ISCALE == 1) WRITE(6,90035) ITEST, ITOL
2104	IF (ISCALE == 2) WRITE(6,90036) ITEST, ITOL
2105	WRITE(6,90037) ERSTATS2(ISCALE,ITOL,ITEST,1), &
2106	ERSTATS2(ISCALE,ITOL,ITEST,4)
2107	WRITE(6,90038) ERSTATS2(ISCALE,ITOL,ITEST,2), &
2108	ERSTATS2(ISCALE,ITOL,ITEST,5)
2109	WRITE(6,90039) ERSTATS2(ISCALE,ITOL,ITEST,3), &
2110	ERSTATS2(ISCALE,ITOL,ITEST,6)
2111	WRITE(6,90044)
2112	WRITE(6,90041) COUNTS(ISCALE,ITOL,ITEST,1,1), &
2113	COUNTS(ISCALE,ITOL,ITEST,4,1), &
2114	COUNTS(ISCALE,ITOL,ITEST,1,2), &
2115	COUNTS(ISCALE,ITOL,ITEST,4,2), &
2116	COUNTS(ISCALE,ITOL,ITEST,1,3), &
2117	COUNTS(ISCALE,ITOL,ITEST,4,3)
2118	WRITE(6,90042) COUNTS(ISCALE,ITOL,ITEST,2,1), &
2119	COUNTS(ISCALE,ITOL,ITEST,5,1), &
2120	COUNTS(ISCALE,ITOL,ITEST,2,2), &
2121	COUNTS(ISCALE,ITOL,ITEST,5,2), &
2122	COUNTS(ISCALE,ITOL,ITEST,2,3), &
2123	COUNTS(ISCALE,ITOL,ITEST,5,3)
2124	WRITE(6,90043) COUNTS(ISCALE,ITOL,ITEST,3,1), &
2125	COUNTS(ISCALE,ITOL,ITEST,6,1), &
2126	COUNTS(ISCALE,ITOL,ITEST,3,2), &
2127	COUNTS(ISCALE,ITOL,ITEST,6,2), &
2128	COUNTS(ISCALE,ITOL,ITEST,3,3), &
2129	COUNTS(ISCALE,ITOL,ITEST,6,3)
2130	WRITE (6,90010)
2131	END DO
2132	END IF
2133	END DO
2134	END IF
2135	END DO
2136
2137	! Total number of solutions performed.
2138	WRITE(6,90025) Total_Solutions
2139	WRITE (6,90010)
2140
2141	! Execution Times.
2142	WRITE(6,90033)
2143	DO ITOL = 5, 12, 1
2144	ITIME = INT(EXECUTION_TIMES(ITOL))
2145	WRITE(6,90034) ITOL, ITIME
2146	END DO
2147	WRITE (6,90010)
2148
2149	! Where to search in output file.
2150	WRITE(6,90032)
2151
2152	! Indicate whether any DVODE_F90 made any error returns.
2153	IF (ERRORS) THEN
2154	WRITE(6,90011)
2155	ELSE
2156	WRITE(6,90012)
2157	END IF
2158
2159	! Format statements follow.
2160	90000 FORMAT (' Class/Problem = A',I1)
2161	90001 FORMAT (' Class/Problem = B',I1)
2162	90002 FORMAT (' Class/Problem = C',I1)
2163	90003 FORMAT (' Class/Problem = D',I1)
2164	90004 FORMAT (' Class/Problem = E',I1)
2165	90005 FORMAT (' Class/Problem = F',I1)
2166	90006 FORMAT (' An error occurred in VODE_F90. ISTATE = ',I3)
2167	90007 FORMAT (' Problem ID = ',I3,/, ' Initial time = ',D15.5,/, &
2168	' Final time = ',D15.5,/,' Initial stepsize = ',D15.5,/, &
2169	' Maximum stepsize = ',D15.5,/,' IWT flag = ',I3,/, &
2170	' Number of ODEs = ',I3,/, ' Error tolerance = ',D15.5,/, &
2171	' Initial solution = ',/,(D15.5))
2172	90008 FORMAT (' Computed and reference solutions and absolute' &
2173	' errors follow:',/,(I3,3D15.5))
2174	90009 FORMAT (' Steps = ',I10,' f-s = ',I10,' J-s = ',I10)
2175	90010 FORMAT (' ____________________________________________________________')
2176	90011 FORMAT (/,' Errors occurred. (Search on ISTATE.)')
2177	90012 FORMAT (/,' No errors occurred.')
2178	90013 FORMAT (' For ITOL = ', I3,' Dense max. observed error = ',D15.5)
2179	90014 FORMAT (I5,6X,I5,3D15.5)
2180	90015 FORMAT (/,'Tolerance',3X,'Problem',4X,'Dense',10X,'Sparse',9X,'Banded')
2181	90016 FORMAT (//,20X,' Results for ITOL = ',I3)
2182	90017 FORMAT (' For ITOL = ', I3,' Sparse max. observed error = ',D15.5)
2183	90018 FORMAT (' For ITOL = ', I3,' Banded max. observed error = ',D15.5)
2184	90019 FORMAT (' The dense and banded results are not identical.')
2185	90020 FORMAT (/,' Maximum Errors for All Problems Follow:')
2186	90021 FORMAT (/,10X,' Maximum Errors for Individual Problems Follow:')
2187	90022 FORMAT (' The original VODE Jacobian was used.')
2188	90023 FORMAT (' The JACSP Jacobian was used.')
2189	90024 FORMAT (/,' Integration Statistics Follow:')
2190	90025 FORMAT (/,' Total number of solutions performed = ',I5)
2191	90026 FORMAT (I5,' Steps: ',3I10)
2192	90027 FORMAT (5X,' Jacs: ',3I10)
2193	90028 FORMAT (5X,' Ders: ',3I10)
2194	90029 FORMAT (/,' Problem',12X,'Dense',4X,'Sparse',4X,'Banded')
2195	90030 FORMAT (' The ODEs were scaled.')
2196	90031 FORMAT (' The ODEs were not scaled.')
2197	90032 FORMAT (//,' To locate the summary results, search on the phrase',/ &
2198	' Summary Statistics Follow in the output file', &
2199	' (stiffoptions.dat).',//)
2200	90033 FORMAT (/,' Tolerance', 10X, 'Total Execution Time')
2201	90034 FORMAT ((4X,I5,10X,I10))
2202	90035 FORMAT (/,' Problem No. = ',I3,/,' ITOL = ',I3,/,' Scaled ODEs', &
2203	13X,'Absolute Errors')
2204	90036 FORMAT (' Problem No. = ',I3,/,' ITOL = ',I3,/,' Unscaled ODEs', &
2205	18X,'Absolute Errors')
2206	90037 FORMAT (' Dense : JACSP - VODE: ',2D15.5)
2207	90038 FORMAT (' Sparse: JACSP - VODE: ',2D15.5)
2208	90039 FORMAT (' Banded: JACSP - VODE: ',2D15.5)
2209	90040 FORMAT (' Nonnegativity will be enforced for this problem.')
2210	90041 FORMAT (' Dense SDJ: ',6I7)
2211	90042 FORMAT (' Sparse SDJ: ',6I7)
2212	90043 FORMAT (' Banded SDJ: ',6I7)
2213	90044 FORMAT (19X,'J',6X,'V',6X,'J',6X,'V',6X,'J',6X,'V')
2214	90045 FORMAT (///,20X,'Summary Statistics Follow')
2215
2216	STOP
2217	END PROGRAM DEMOSTIFF

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source: palm/trunk/UTIL/chemistry/gasphase_preproc/kpp/int/DVODE/stiffoptions.f90 @ 2696

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