8 def __convert__(self,valeur):
9 if type(valeur) == types.StringType: return None
10 if len(valeur) != self.ntuple: return None
14 return "Date : jj/mm/aaaa "
21 def __init__(self,ntuple):
24 def __convert__(self,valeur):
25 if type(valeur) == types.StringType:
27 if len(valeur) != self.ntuple:
32 return "Tuple de %s elements" % self.ntuple
36 JdC = JDC_CATA (code = 'TELEMAC',
39 # ======================================================================
40 # Catalog entry for the MAP function : c_pre_interfaceBody_mesh
41 # ======================================================================
43 # -----------------------------------------------------------------------
44 INITIALIZATION = PROC(nom = "INITIALIZATION",op = None,
45 # -----------------------------------------------------------------------
47 fr = "Initialisation des fichiers d'entrée et de sortie",
48 ang = "Input and Output files initialization",
49 UIinfo = { "groupes" : ( "CACHE", )},
50 #UIinfo = { "groupes" : ( "iiii", )},
52 # ------------------------------------
53 Title = SIMP( statut = 'o',typ = 'TXM',
54 # ------------------------------------
55 fr = 'Titre du cas etudie. Ce titre figurera sur les dessins.',
56 ang = 'Title of the case being considered. This title shall be marked on the drawings.'),
57 #Working_Directory = SIMP( statut='o',typ='Repertoire',defaut='/tmp'),
59 # ------------------------------------
60 Input_Files = FACT(statut='o',
61 # ------------------------------------
63 # Dictionary = SIMP( statut='o', typ = ('Fichier', 'Dico (*.dico);;All Files (*)',),
64 # defaut='telemac2d.dico',
65 # fr='Dictionnaire des mots cles.', ang='Key word dictionary.',),
66 # PN : le mot cle doit etre dans le dictionnaire et repris du catalogue mais n
69 # ------------------------------------
70 Geometry_File_Format = SIMP( statut = 'o', typ = 'TXM',
71 # ------------------------------------
72 into = ['Serafin', 'MED', 'SerafinD'],
74 fr = 'Format du fichier de geometrie. Les valeurs possibles sont : \n \
75 - SERAFIN : format standard simple precision pour Telemac; \n \
76 - SERAFIND: format standard double precision pour Telemac; \n \
77 - MED : format MED base sur HDF5',
78 ang = 'Results file format. Possible values are: \n\
79 - SERAFIN : classical single precision format in Telemac;\n\
80 - SERAFIND: classical double precision format in Telemac;\n\
81 - MED : MED format based on HDF5',) ,
83 # ------------------------------------
84 Geometry_File = SIMP( statut = 'o',
85 # ------------------------------------
86 typ = ('Fichier', 'Geo Files (*.geo);;All Files (*)',),
87 fr = 'Nom du fichier contenant le maillage du calcul a realiser.',
88 ang = 'Name of the file containing the mesh. \n\
89 This file may also contain the topography and the friction coefficients.'),
91 #Steering_File = SIMP( statut = 'o', typ = ('Fichier', 'Steering Files (*.cas);;All Files (*)',),),
94 # ------------------------------------
95 Fortran_File = SIMP(statut = 'f',
96 # ------------------------------------
97 typ = ('Fichier', 'Fortran files (*.f);;All Files (*)'),
98 fr = 'Nom du fichier a soumettre',
99 ang = 'Name of FORTRAN file to be submitted',),
101 # ------------------------------------
102 Bottom_Topography_File = SIMP( statut = 'f',
103 # ------------------------------------
104 typ = ('Fichier', 'Geo Files (*.geo);;All Files (*)',),
105 fr = "Nom du fichier eventuel contenant la bathymetrie associee au maillage. \
106 Si ce mot-cle est utilise; c'est cette bathymetrie qui sera utilisee pour le calcul.",
107 ang = 'Name of the possible file containing the bathymetric data.\
108 Where this keyword is used, these bathymetric data shall be used in the computation.',
111 # ------------------------------------
112 Bottom_Smoothings = SIMP( statut = 'o',typ = 'I', defaut = 0 ,
113 # ------------------------------------
114 fr = 'Nombre de lissages effectues sur la topographie. chaque lissage, effectue a l aide dune matrice de masse, est conservatif.\n\
115 Utilise lorsque les donnees de bathymetrie donnent des resultats trop irreguliers apres interpolation.',
116 ang = 'Number of smoothings on bottom topography. each smoothing is mass conservative. \n\
117 to be used when interpolation of bathymetry on the mesh gives very rough results.',),
119 # ------------------------------------
120 Boundary_Conditions_File = SIMP( statut = 'o',
121 # ------------------------------------
122 typ = ('Fichier', 'Boundary Condition (*.cli);;All Files (*)',),
123 fr = 'Nom du fichier contenant les types de conditions aux limites. Ce fichier est rempli de facon automatique\n\
124 par le mailleur au moyen de couleurs affectees aux noeuds des frontieres du domaine de calcul.',
125 ang = 'Name of the file containing the types of boundary conditions. This file is filled automatically\n\
126 by the mesh generator through through colours that are assigned to the boundary nodes.',),
129 # ------------------------------------
130 Validation = FACT( statut = 'f',
131 # ------------------------------------
132 #PNPN--> creer le Mot_clef simple Validation si ce fact existe
134 # ------------------------------------
135 Reference_File_Format = SIMP( statut = 'o',
136 # ------------------------------------
138 into = ['Serafin','MED','SerafinD'],
140 fr = 'Format du fichier de resultats. Les valeurs possibles sont : \n\
141 - SERAFIN : format standard simple precision pour Telemac; \n\
142 - SERAFIND: format standard double precision pour Telemac; \n\
143 - MED : format MED base sur HDF5' ,
144 ang = 'Results file format. Possible values are:\n \
145 - SERAFIN : classical single precision format in Telemac;\n\
146 - SERAFIND: classical double precision format in Telemac; \n\
147 - MED : MED format based on HDF5' ,),
149 # ------------------------------------
150 Reference_File = SIMP( statut = 'o',
151 # ------------------------------------
152 typ = ('Fichier', 'Reference File (*.ref);;All Files (*)',),
153 fr = 'Fichier de resultats de reference pour la validation. Les resultats a placer dans ce fichier seront a ecrire sur le canal 22.',
154 ang = 'Binary-coded result file for validation. The results to be entered into this file shall be written on channel 22.',),
156 ), # Fin de Validation
158 # ------------------------------------
159 Formatted_And_Binary_Files = FACT( statut = 'f',
160 # ------------------------------------
162 # ------------------------------------
163 Formatted_Data_File_1 = SIMP( statut = 'f', typ = ('Fichier', 'formated File (*.txt);;All Files (*)',),
164 # ------------------------------------
165 fr = "Fichier de donnees formate mis a la disposition de l''utilisateur. \n\
166 Les donnees de ce fichier seront a lire sur le canal 26.",
167 ang = 'Formatted data file made available to the user.\n\
168 The data in this file shall be read on channel 26.',),
170 # ------------------------------------
171 Formatted_Data_File_2 = SIMP( statut = 'f', typ = ('Fichier', 'formated File (*.txt);;All Files (*)',),
172 # ------------------------------------
173 fr = "Fichier de donnees formate mis a la disposition de l'utilisateur. \n\
174 Les donnees de ce fichier seront a lire sur le canal 27.",
175 ang = "Formatted data file made available to the user.\n\
176 The data in this file shall be read on channel 27.",),
178 # ------------------------------------
179 Binary_Data_File_1 = SIMP( statut = 'f', typ = ('Fichier', 'All Files (*)',),
180 # ------------------------------------
181 fr = 'Fichier de donnees code en binaire mis a la disposition de l utilisateur. \n\
182 Les donnees de ce fichier seront a lire sur le canal 24.',
183 ang = 'Binary-coded data file made available to the user.\n\
184 The data in this file shall be read on channel 24.',),
186 # ------------------------------------
187 Binary_Data_File_2 = SIMP( statut = 'f', typ = ('Fichier', 'All Files (*)',),
188 # ------------------------------------
189 fr = 'Fichier de donnees code en binaire mis a la disposition de l utilisateur.\n\
190 Les donnees de ce fichier seront a lire sur le canal 25.',
191 ang = 'Binary-coded data file made available to the user. \n\
192 The data in this file shall be read on channel 25.',),
194 ), # fin Formatted_And_Binary_Files
196 ), # Fin de InputFile
198 # -----------------------------------------------------------------------
199 Initial_State = FACT(statut='o',
200 # -----------------------------------------------------------------------
202 # ------------------------------------
203 Initial_Conditions = SIMP(statut = 'o',typ = 'TXM',
204 # ------------------------------------
205 into = ['Zero elevation','Constant elevation','Zero depth','Constant depth','Special','TPXO satellite altimetry'],
206 defaut = 'Zero elevation',
207 fr = "Permet de definir les conditions initiales sur les hauteurs d'eau. Les valeurs possibles sont :\n\
208 - COTE NULLE. Initialise la cote de surface libre a 0. \nLes hauteurs d'eau initiales sont alors retrouvees en faisant la difference entre les cotes de surface libre et du fond. \n\
209 - COTE CONSTANTE . Initialise la cote de surface libre a la valeur donnee par le mot-cle COTE INITIALE. Les hauteurs d'eau initiales sont calculees comme precedemment.\n\
210 - HAUTEUR NULLE .Initialise les hauteurs d'eau a 0. \n\
211 - HAUTEUR CONSTANTE. Initialise les hauteurs d'eau a la valeur donnee par le mot-cle HAUTEUR INITIALE. \n\
212 - PARTICULIERES. Les conditions initiales sur la hauteur d'eau doivent etre precisees dans le sous-programme CONDIN. \n\
213 - ALTIMETRIE SATELLITE TPXO. Les conditions initiales sur la hauteur d'eau et les vitesses sont etablies sur \n\
214 la base des donnees satellite TPXO dont les 8 premiers constistuents ont ete extraits et sauves dans le fichier\n\
215 BASE DE DONNEES DE MAREE." ,
216 ang = 'Makes it possible to define the initial conditions with the water depth. The possible values are : \n\
217 - ZERO ELEVATION. Initializes the free surface elevation to 0. \n The initial water depths are then found by computing the difference between the free surface and the bottom. \n\
218 - CONSTANT ELEVATION. Initializes the water elevation to the value given by the keyword \n\
219 - INITIAL ELEVATION. The initial water depths are computed as in the previous case. \n\
220 - ZERO DEPTH. Initializes the water depths to 0. \n\
221 - CONSTANT DEPTH. Initializes the water depths to the value givenby the key-word INITIAL DEPTH. \n\
222 - SPECIAL. The initial conditions with the water depth should be stated in the CONDIN subroutine. \n\
223 - TPXO SATELITE ALTIMETRY. The initial conditions on the free surface and velocities are established from the TPXO satellite program data,\n the harmonic constituents of which are stored in the TIDE DATA BASE file.', ),
225 # ------------------------------------
226 b_initial_elevation = BLOC (condition = "Initial_Conditions == 'Constant elevation'",
227 # ------------------------------------
228 # ------------------------------------
229 Initial_Elevation = SIMP(statut = 'o',typ = 'R',
230 # ------------------------------------
231 fr = 'Valeur utilisee avec l''option : CONDITIONS INITIALES - COTE CONSTANTE',
232 ang = 'Value to be used with the option : INITIAL CONDITIONS -CONSTANT ELEVATION' ),
233 ) , # fin b_initial_elevation
235 # ------------------------------------
236 b_initial_depth = BLOC (condition = "Initial_Conditions == 'Constant depth'",
237 # ------------------------------------
238 # ------------------------------------
239 Initial_Depth = SIMP(statut = 'o',typ = 'R',
240 # ------------------------------------
241 fr = 'Valeur utilisee avec l''option : CONDITIONS INITIALES :-HAUTEUR CONSTANTE-',
242 ang = 'Value to be used along with the option: INITIAL CONDITIONS -CONSTANT DEPTH-' ),
243 ),# fin b_initial_depth
245 # ------------------------------------
246 b_special = BLOC (condition = "Initial_Conditions == 'Special'",
247 # ------------------------------------
248 # ------------------------------------
249 Consigne = SIMP(statut = "o",homo = 'information',typ = "TXM",
250 # ------------------------------------
251 defaut = "The initial conditions with the water depth should be stated in the CONDIN subroutine"),
254 #PNPN il faut changer la condition pour que cela soit dans maree. il faut une position = global_jdc et remonter # cela
255 # ------------------------------------
256 b_initial_TPXO = BLOC (condition = "Initial_Conditions == 'TPXO satellite altimetry'",
257 # ------------------------------------
258 # ------------------------------------
259 Ascii_Database_For_Tide = SIMP( statut = 'o',
260 # ------------------------------------
261 typ = ('Fichier', 'All Files (*)',),
262 fr = 'Base de donnees de constantes harmoniques tirees du fichier du modele de maree',
263 ang = 'Tide data base of harmonic constituents extracted from the tidal model file',),
264 ), # fin b_initial_TPXO
266 ), # fin Initial_State
269 # ------------------------------------
270 Computation_Continued = SIMP( statut = 'o',typ = bool,defaut = False,position = "global_jdc"),
271 # ------------------------------------
273 # ------------------------------------
274 b_comput_con = BLOC(condition = 'Computation_Continued == True',
275 Computation_Continued_Settings = FACT(statut = 'o',
277 # ------------------------------------
278 Previous_Computation_File_Format = SIMP( statut = 'o',typ = 'TXM',
279 # ------------------------------------
280 into = ['Serafin','MED','SerafinD'],
282 fr = 'Format du fichier de resultats du calcul precedent. Les valeurs possibles sont : \n\
283 - SERAFIN : format standard simple precision pour Telemac; \n\
284 - SERAFIND: format standard double precision pour Telemac; \n\
285 - MED : format MED base sur HDF5',
286 ang = 'Previous computation results file format. Possible values are: \n\
287 - SERAFIN : classical single precision format in Telemac; \n\
288 - SERAFIND: classical double precision format in Telemac; \n\
289 - MED : MED format based on HDF5',),
291 # ------------------------------------
292 Previous_Computation_File = SIMP( statut = 'o',
293 # ------------------------------------
294 typ = ('Fichier', 'Computation File (*.res);;All Files (*)',),
295 fr = "Nom d'un fichier contenant les resultats d'un calcul precedent realise sur le meme maillage \n\
296 et dont le dernier pas de temps enregistre va fournir les conditions initiales pour une suite de de calcul.",
297 ang = 'Name of a file containing the results of an earlier computation which was made on the same mesh.\n\
298 The last recorded time step will provid the initial conditions for the new computation.',
300 # ------------------------------------
301 Initial_Time_Set_To_Zero = SIMP(typ = bool, statut = 'o',
302 # ------------------------------------
303 fr = 'Remet le temps a zero en cas de suite de calcul',
304 ang = 'Initial time set to zero in case of restart',
307 # ------------------------------------
308 Record_Number_For_Restart = SIMP(typ = 'I', statut = 'o', defaut = 0,
309 # ------------------------------------
310 fr = "numero de l'enregistrement de depart dans le fichier du calcul precedent. 0 signifie qu'on prend le dernier enregistrement",
311 ang = "record number to start from in the previous computation file, 0 for last record" ),
314 ),# fin BLOC b_comput_con
316 # ------------------------------------
317 Coupling = FACT( statut = 'o',
318 # ------------------------------------
319 # PNPNPN Attention 1 seul choix possible
320 fr = 'Liste des codes avec lesquels on couple Telemac-2D',
321 ang = 'List of codes to be coupled with Telemac-2D',
323 # ------------------------------------
324 Sisyphe = SIMP(statut = 'o',typ = bool,defaut = False ,
325 # ------------------------------------
326 fr = 'couplage interne avec Sisyphe',
327 ang = 'internal coupling with Sisyphe'),
329 # ------------------------------------
330 Tomawac = SIMP(statut = 'o',typ = bool,defaut = False,
331 # ------------------------------------
332 fr = 'couplage interne avec Tomawac',
333 ang = 'internal coupling with Tomawac'),
335 # ------------------------------------
336 Delwacq = SIMP(statut = 'o',typ = bool,defaut = False,
337 # ------------------------------------
338 fr = 'couplage interne avec Delwacq',
339 ang = 'internal coupling with Delwacq'),
340 # PNPNPN Attention : il faut des mots cles si Delwacq. a voir avec Soizic
345 # ------------------------------------
346 Parallel_Computation = SIMP(statut = 'o',typ = 'TXM',
347 # ------------------------------------
348 # Ce mot clef n existe pas dans le dico
349 into = ['Sequentiel','Parallel'],
350 defaut = 'Sequentiel',),
352 # ------------------------------------
353 b_para = BLOC(condition = 'Parallel_Computation == "Parallel"',
354 # ------------------------------------
355 # ------------------------------------
356 Parallel_Processors = SIMP(statut = 'o',typ = 'I',
357 # ------------------------------------
358 val_min = 0,defaut = 1,
359 fr = 'NOMBRE DE PROCESSEURS EN CALCUL PARALLELE \n\
360 0 : 1 machine, compilation sans bibliotheque de parallelisme \n\
361 1 : 1 machine, compilation avec bibliotheque de parallelisme \n\
362 2 : 2 processeurs ou machines en parallele etc... ',
363 ang = 'NUMBER OF PROCESSORS FOR PARALLEL PROCESSING \n\
364 0 : 1 machine, compiling without parallel library \n\
365 1 : 1 machine, compiling with a parallel library \n\
366 2 : 2 processors or machines in parallel'),
371 # -----------------------------------------------------------------------
372 TIDE_PARAMETERS = PROC(nom = "TIDE_PARAMETERS",op = None,
373 # -----------------------------------------------------------------------
374 # ------------------------------------
375 Inputs_Outputs_For_Tide = FACT( statut = 'o',
376 # ------------------------------------
378 # ------------------------------------
379 Harmonic_Constants_File = SIMP( statut = 'o',
380 # ------------------------------------
381 typ = ('Fichier', 'All Files (*)',),
382 fr = 'Constantes harmoniques extraites du fichier du modele de maree',
383 ang = 'Harmonic constants extracted from the tidalmodel file',),
385 # ------------------------------------
386 Tidal_Model_File = SIMP( statut = 'o',
387 # ------------------------------------
388 typ = ('Fichier', 'All Files (*)',),
389 fr = 'Fichier de geometrie du modele dont sont extraites les constantes harmoniques',
390 ang = 'Geometry file of the model from which harmonic constituents are extracted',),
392 ), # Fin Inputs_Outputs_For_Tide
394 # ------------------------------------
395 Location = FACT( statut = 'o',
396 # ------------------------------------
397 # ------------------------------------
398 Geographic_System = SIMP(statut = 'o',typ = 'TXM',
399 # ------------------------------------
400 into = ["Defined by user", "WGS84 longitude/latitude in real degrees", "WGS84 nothern UTM",\
401 "WGS84 southern UTM","Lambert", "Mercator",],
402 defaut = "Defined by user",
403 fr = 'Systeme de coordonnees geographiques dans lequel est construit le modele numerique.',
404 ang = 'Geographic coordinates system in which the numerical model is built.',),
406 # ------------------------------------
407 b_geo_plan = BLOC(condition = "Geographic_System in ['WGS84 nothern UTM','WGS84 southern UTM','Lambert']",
408 # ------------------------------------
410 # ------------------------------------
411 Zone_Number_In_Geographic_System = SIMP(statut = 'f',typ = 'TXM',
412 # ------------------------------------
413 into = [ 'Lambert 1 north', 'Lambert 2 center', 'Lambert 3 south', \
414 'Lambert 4 corsica', 'Lambert 2 extended', 'UTM zone,E.G.'],
415 fr = "Numero de zone (fuseau ou type de projection) lors de l'utilisation d'une projection plane.\n \
416 Indiquer le systeme geographique dans lequel est construit le modele numerique avec le mot-cle SYSTEME GEOGRAPHIQUE",
417 ang = 'Number of zone when using a plane projection. \n\
418 Indicate the geographic system in which the numerical model is built with the keyword GEOGRAPHIC SYSTEM'),
422 # ------------------------------------
423 Physical_Parameters = FACT(statut = 'o',
424 # ------------------------------------
426 # ------------------------------------
427 Tide_Generating_Force = SIMP(statut = 'o',
428 # ------------------------------------
429 typ = bool, defaut = False),
431 # ------------------------------------
432 b_Tide = BLOC(condition = "Tide_Generating_Force == True",
433 # ------------------------------------
434 # ------------------------------------
435 Longitude_Of_Origin_Point = SIMP(typ = 'R',
436 # ------------------------------------
437 statut = 'o', defaut = 48.,
438 fr = 'Fixe la valeur de la longitude du point origine du modele, lors de l utilisation de la force generatrice de la maree.',
439 ang = 'Give the value of the longitude of the origin point of the model, when taking into account of the tide generator force.',),
441 # ------------------------------------
442 Tidal_Data_Base = SIMP(statut = 'o',typ = 'TXM',
443 # ------------------------------------
444 # Soizic . Il faudrait une consigne ? avec des blocs ?
445 # en suspens pour JMJ
446 into = [ "JMJ", "TPXO", "Miscellaneous (LEGOS-NEA, FES20XX, PREVIMER...)",],
447 fr = 'Pour JMJ, renseigner la localisation du fichier bdd_jmj et geofin dans les mots-cles BASE DE DONNEES DE MAREE \n\
448 et FICHIER DU MODELE DE MAREE. Pour TPXO, LEGOS-NEA, FES20XX et PREVIMER, l utilisateur doit telecharger les fichiers \n\
449 de constantes harmoniques sur internet',
450 ang = 'For JMJ, indicate the location of the files bdd_jmj and geofin with keywords TIDE DATA BASE and TIDAL MODEL FILE.\n\
451 For TPXO, LEGOS-NEA, FES20XX and PREVIMER, the user has to download files of harmonic constituents on the internet',),
453 # ------------------------------------
454 b_tpxo = BLOC(condition = "Tidal_Data_Base == 'TPXO'",
455 # ------------------------------------
457 # ------------------------------------
458 Minor_Constituents_Inference = SIMP( statut = 'o',typ = bool,
459 # ------------------------------------
461 fr = 'Interpolation de composantes harmoniques mineures a partir de celles lues dans les \n\
462 fichiers d entrees lies aux mots-cles BASE BINAIRE 1 DE DONNEES DE MAREE et BASE BINAIRE 2 DE DONNEES DE MAREE',
463 ang = 'Inference of minor constituents from the one read in input files linked to \n\
464 keywords BINARY DATABASE 1 FOR TIDE and BINARY DATABASE 2 FOR TIDE',),
468 # ------------------------------------
469 Binary_Database_1_For_Tide = SIMP( statut = 'o',
470 # ------------------------------------
471 typ = ('Fichier', '(All Files (*),)',),
472 fr = 'Base de donnees binaire 1 tiree du fichier du modele de maree.\n\
473 Dans le cas des donnees satellitaires de TPXO, ce fichier correspond aux donnees de niveau d''eau, par exemple h_tpxo7.2',
474 ang = 'Binary database 1 extracted from the tidal model file.\n\
475 In the case of the TPXO satellite altimetry model, this file should be for free surface level, for instance h_tpxo7.2',),
477 # ------------------------------------
478 Binary_Database_2_For_Tide = SIMP( statut = 'o',
479 # ------------------------------------
480 typ = ('Fichier', '(All Files (*),)',),
481 fr= 'Base de donnees binaire 2 tiree du fichier du modele de maree.\n\
482 Dans le cas des donnees satellitaires de TPXO, ce fichier correspond aux donnees de vitesse de marrees, par exemple u_tpxo7.2',
483 ang = 'Binary database 2 extracted from the tidal model file.\n\
484 In the case of the TPXO satellite altimetry model, this file should be for tidal velocities, for instance u_tpxo7.2' ),
486 ),#fin du bloc b_tpxo
487 ), # Fin du Bloc b_Tide
489 # ------------------------------------
490 Option_For_Tidal_Boundary_Conditions = SIMP( statut = 'o',
491 # ------------------------------------
492 typ = 'TXM', defaut = 'No tide',
493 into = ['No tide', 'Real tide (recommended methodology)', 'Astronomical tide', \
494 'Mean spring tide', 'Mean tide', 'Mean neap tide', \
495 'Astronomical neap tide', 'Real tide (methodology before 2010)'],),
497 # ------------------------------------
498 b_Option_B = BLOC(condition = 'Option_For_Tidal_Boundary_Conditions!= "No tide"',
499 # ------------------------------------
500 # ------------------------------------
501 Coefficient_To_Calibrate_Tidal_Range = SIMP(statut = 'o',
502 # ------------------------------------
503 typ = 'R', defaut = 1.,
504 fr = 'Coefficient pour ajuster le marnage de l''onde de maree aux frontieres maritimes',
505 ang = 'Coefficient to calibrate the tidal range of tidal wave at tidal open boundary conditions'),
507 # ------------------------------------
508 Coefficient_To_Calibrate_Tidal_Velocities = SIMP(statut = 'o',
509 # ------------------------------------
510 typ = 'R', defaut = 999999,
511 fr = 'Coefficient pour ajuster les composantes de vitesse de l''onde de maree aux frontieres maritimes.\n\
512 La valeur par defaut 999999. signifie que c''est la racine carree du Coefficient_De_Calage_Du_Marnage qui est prise',
513 ang = 'Coefficient to calibrate the tidal velocities of tidal wave at tidal open boundary conditions.\n\
514 Default value 999999. means that the square root of Coefficient_To_Calibrate_Tidal_Range is taken'),
516 # ------------------------------------
517 Coefficient_To_Calibrate_Sea_Level = SIMP(statut = 'o',typ = 'R',
518 # ------------------------------------
520 fr = 'Coefficient pour ajuster le niveau de mer',
521 ang = 'Coefficient to calibrate the sea level'),
524 ), #fin Physical_Parameters
525 ) # Fin TIDE_PARAMETERS
527 # -----------------------------------------------------------------------
528 BOUNDARY_CONDITIONS = PROC(nom = "BOUNDARY_CONDITIONS",op = None,
529 # -----------------------------------------------------------------------
530 fr = 'On donne un ensemble de conditions par frontiere liquide',
531 ang = 'One condition set per liquid boundary is given',
532 UIinfo = { "groupes" : ( "CACHE", )},
533 #UIinfo = { "groupes" : ( "iiii", )},
534 # Dans l ideal il faut aller regarder selon les groupes dans le fichier med
535 # en sortie il faut aller chercher le .cli qui va bien
536 #Liquid_Boundaries = FACT(statut = 'f',max = '**',
537 # Options = SIMP(statut = 'f',typ = 'I',into = ['classical boundary conditions','Thompson method based on characteristics'])
538 # Prescribed_Flowrates = SIMP(statut = 'f',typ = 'R'),
539 # Prescribed_Elevations = SIMP(statut = 'f',typ = 'R'),
540 # Prescribed_Velocity = SIMP(statut = 'f',typ = 'R'),
543 # Il va falloir une "traduction dans le langage du dico"
544 # Il faut seulement l un des 3
546 # ------------------------------------
547 Liquid_Boundaries = FACT(statut = 'o',max = '**',
548 # ------------------------------------
550 # ------------------------------------
551 Options = SIMP(statut = 'f',typ = 'I',
552 # ------------------------------------
553 into = ['Classical boundary conditions','Thompson method based on characteristics'],
554 fr = 'On donne 1 entier par frontiere liquide',
555 ang = 'One integer per liquid boundary is given',),
557 # ------------------------------------
558 Type_Condition = SIMP(statut = 'o',typ = 'TXM',
559 # On ajoute le type pour rendre l 'ihm plus lisible
560 # mais ce mot-cle n existe pas dans le dico
561 # ------------------------------------
562 into = ['Prescribed Flowrates', 'Prescribed Elevations', 'Prescribed Velocity'],),
564 # ------------------------------------
565 b_Flowrates = BLOC (condition = "Type_Condition == 'Prescribed Flowrates'",
566 # ------------------------------------
567 # ------------------------------------
568 Prescribed_Flowrates = SIMP(statut = 'o',
569 # ------------------------------------
571 fr = ' Valeurs des debits imposes aux frontieres liquides entrantes.\n\
572 Lire la partie du mode d''emploi consacree aux conditions aux limites',
573 ang = 'Values of prescribed flowrates at the inflow boundaries.\n\
574 The section about boundary conditions is to be read in the manual'),
577 # ------------------------------------
578 b_Elevations = BLOC (condition = "Type_Condition == 'Prescribed Elevations'",
579 # ------------------------------------
580 # ------------------------------------
581 Prescribed_Elevations = SIMP(statut = 'o',typ = 'R',
582 # ------------------------------------
583 fr = 'Valeurs des cotes imposees aux frontieres liquides entrantes.\n\
584 Lire la partie du mode d''emploi consacree aux conditions aux limites',
585 ang = 'Values of prescribed elevations at the inflow boundaries.\n\
586 The section about boundary conditions is to be read in the manual'),
587 ), # fin b_Elevations
589 # ------------------------------------
590 b_Velocity = BLOC (condition = "Type_Condition == 'Prescribed Velocity'",
591 # ------------------------------------
592 # ------------------------------------
593 Prescribed_Velocities = SIMP(statut = 'o',typ = 'R',
594 # ------------------------------------
595 fr = 'Valeurs des vitesses imposees aux frontieres liquides entrantes.\n\
596 Lire la partie du mode d''emploi consacree aux conditions aux limites',
597 ang = 'Values of prescribed velocities at the liquid inflow boundaries.\n\
598 Refer to the section dealing with the boundary conditions'),
601 ), # fin des Liquid_Boundaries
603 # ------------------------------------
604 Liquid_Boundaries_File = SIMP( statut = 'f',
605 # ------------------------------------
606 typ = ('Fichier', 'All Files (*)',),
607 fr = 'Fichier de variations en temps des conditions aux limites.\n\
608 Les donnees de ce fichier seront a lire sur le canal 12.',
609 ang = 'Variations in time of boundary conditions. Data of this file are read on channel 12.',
613 #PNPN Attention dans le Dico STAGE-DISCHARGE CURVES
614 #PNPN regarder le document de reference pour changer non programme
615 # ------------------------------------
616 Stage_Discharge_Curves = SIMP(statut = 'f',typ = 'TXM',
617 # ------------------------------------
618 into = ["No one","Z(Q)","Q(Z)"],
619 fr = 'Indique si une courbe de tarage doit etre utilisee pour une frontiere',
620 ang = 'Says if a discharge-elevation curve must be used for a given boundary',),
622 # ------------------------------------
623 b_discharge_curve = BLOC (condition = "Stage_Discharge_Curves != 'no'",
624 # ------------------------------------
625 # ------------------------------------
626 Stage_Discharge_Curves_File = SIMP( statut = 'f',
627 # ------------------------------------
628 typ = ('Fichier', 'All Files (*)',),
629 fr = 'Nom du fichier contenant les courbes de tarage',
630 ang = 'Name of the file containing stage-discharge curves',),
631 ), # fin b_discharge_curve
633 # ------------------------------------
634 Elements_Masked_By_User = SIMP(statut = 'o',typ = bool,
635 # ------------------------------------
637 fr = 'Si oui remplir le sous-programme maskob',
638 ang = 'if yes rewrite subroutine maskob',),
640 # ------------------------------------
641 maskob = BLOC (condition = 'Elements_Masked_By_User == True',
642 # ------------------------------------
643 # ------------------------------------
644 Consigne = SIMP(statut = "o",homo = 'information',typ = "TXM",
645 # ------------------------------------
646 defaut = "Remplir le sous-programme maskob"),
649 ) # fin Boundary_Conditions
651 # -----------------------------------------------------------------------
652 NUMERICAL_PARAMETERS = PROC(nom = "NUMERICAL_PARAMETERS",op = None,
653 # -----------------------------------------------------------------------
655 UIinfo = { "groupes" : ( "CACHE", )},
656 #UIinfo = { "groupes" : ( "iiii", )},
658 # ------------------------------------
659 Equations = SIMP(statut = 'o',typ = 'TXM',
660 # ------------------------------------
661 into = ['Saint-Venant EF','Saint-Venant VF','Boussinesq'],
662 defaut = 'Saint-Venant EF',
663 fr = 'Choix des equations a resoudre',
664 ang = 'Choice of equations to solve',),
666 # ------------------------------------
667 Treatment_Of_The_Linear_System = SIMP(statut = 'o', typ = 'TXM',
668 # ------------------------------------
669 into = ["Coupled", "Wave equation"],
670 defaut = "Coupled",),
672 # ------------------------------------
673 Finite_Volume_Scheme = SIMP( statut = 'o',typ = 'TXM',
674 # ------------------------------------
675 into = [ "Roe scheme", "Kinetic order 1", "Kinetic order 2", "Zokagoa scheme order 1",\
676 "Tchamen scheme order 1", "HLLC scheme order 1", "WAF scheme order 2"],
677 defaut = "Kinetic order 1",),
679 # ------------------------------------
680 Solver_Definition = FACT(statut = 'o',
681 # ------------------------------------
683 # ------------------------------------
684 Solver = SIMP(statut = 'o',typ = 'TXM',
685 # ------------------------------------
686 into = ["Conjugate gradient", "Conjugate residual","Conjugate gradient on a normal equation",\
687 "Minimum error", "CGSTAB", "GMRES", "Direct",],
688 fr = 'Permet de choisir le solveur utilise pour la resolution de l''etape de propagation. \n\
689 Toutes les methodes proposees actuellement s''apparentent au Gradient Conjugue. Ce sont :\n\
690 1 : gradient conjugue 2 : residu conjugue 3 : gradient conjugue sur equation normale \n\
691 4 : erreur minimale 5 : gradient conjugue carre (non programme) 6 : gradient conjugue carre stabilise (cgstab)\n\
692 7 : gmres (voir aussi option du solveur) 8 : direct',
693 ang = 'Makes it possible to select the solver used for solving the propagation step.\n\
694 All the currently available methods are variations of the Conjugate Gradient method. They are as follows: \n\
695 1: conjugate gradient 2: conjugate residual 3: conjugate gradient on a normal equation\n\
696 4: minimum error 5: conjugate gradient squared (not implemented) 6: conjugate gradient squared stabilised (cgstab) \n\
697 7: gmres (see option for solver) 8: direct',),
699 # ------------------------------------
700 b_gmres = BLOC (condition = "Solver == 'GMRES'",
701 # ------------------------------------
702 # ------------------------------------
703 Solver_Option = SIMP(statut = 'o',typ = 'I', defaut = 2, val_min = 2,val_max = 15,
704 # ------------------------------------
705 fr = 'la dimension de l''espace de KRILOV',
706 ang = 'dimension of the KRYLOV space',),
709 # ------------------------------------
710 Solver_Accuracy = SIMP(statut = 'o',typ = 'R', defaut = 1e-4,
711 # ------------------------------------
712 fr = 'Precision demandee pour la resolution de l''etape de propagation (cf. Note de principe).',
713 ang = 'Required accuracy for solving the propagation step (refer to Principle note).',),
715 # ------------------------------------
716 Maximum_Number_Of_Iterations_For_Solver = SIMP(statut = 'o',typ = 'I', defaut = 100,
717 # ------------------------------------
718 fr = 'Les algorithmes utilises pour la resolution de l''etape de propagation etant iteratifs, \n\
719 il est necessaire de limiter le nombre d''iterations autorisees.\n\
720 Remarque : un maximum de 40 iterations par pas de temps semble raisonnable.',
721 ang = 'Since the algorithms used for solving the propagation step are iterative, \
722 the allowed number of iterations should be limited.\n\
723 Note: a maximum number of 40 iterations per time step seems to be reasonable.',),
727 # ------------------------------------
728 Linearity = FACT(statut = 'f',
729 # ------------------------------------
730 # ------------------------------------
731 Continuity_Correction = SIMP(typ = bool, statut = 'o',
732 # ------------------------------------
734 fr = 'Corrige les vitesses sur les points avec hauteur imposee ou l equation de continuite n a pas ete resolue',
735 ang = 'Correction of the velocities on points with a prescribed elevation, where the continuity equation has not been solved',),
739 # ------------------------------------
740 Precondionning_setting = FACT(statut = 'f',
741 # ------------------------------------
743 # ------------------------------------
744 Preconditioning = SIMP(statut = 'o',typ = 'TXM',max="**",
745 # ------------------------------------
746 # PNPN Soizic ? Est ce que c'est une liste
747 # Comment fait-on le into est faux : voir l aide
748 # PN Je propose qu 'on puisse faire +sieurs choix et qu on recalcule en sortie
749 # ou on propose des choix croisés parce que toutes les combinaisons ne sont pas possibles ?
751 into = [ "Diagonal", "No preconditioning", "Diagonal condensee", "Crout", "Gauss-Seidel", ],
752 defaut=("Diagonal",), homo="SansOrdreNiDoublon",
753 fr='Permet de preconditionner le systeme de l etape de propagation afin d accelerer la convergence \n\
754 lors de sa resolution. Certains preconditionnements sont cumulables : (les diagonaux 2 ou 3 avec les autres)\n\
755 Pour cette raison on ne retient que les nombres premiers pour designer les preconditionnements. Si l on souhaite en cumuler\n\
756 plusieurs on formera le produit des options correspondantes.',
757 ang='Choice of the preconditioning in the propagation step linear system that the convergence is speeded up\n\
758 when it is being solved.Some operations (either 2 or 3 diagonal preconditioning) can be performed concurrently with the others.\n\
759 Only prime numbers are therefore kept to denote the preconditioning operations. When several of them are to be performed concurrently,\n\
760 the product of relevant options shall be made.',
762 # ------------------------------------
763 C_U_Preconditioning = SIMP(typ = bool, statut = 'o', defaut=False,
764 # ------------------------------------
765 fr = 'Changement de variable de H en C dans le systeme lineaire final',
766 ang = 'Change of variable from H to C in the final linear system'
769 ),# fin Preconditionnement
771 # ------------------------------------
772 Matrix_Informations = FACT(statut = 'f',
773 # ------------------------------------
774 # ------------------------------------
775 Matrix_Vector_Product = SIMP(statut = 'o',typ = 'TXM',
776 # ------------------------------------
777 into = ["Classic", "Frontal"],
779 fr = 'attention, si frontal, il faut une numerotation speciale des points',
780 ang = 'beware, with option 2, a special numbering of points is required',
782 # ------------------------------------
783 Matrix_Storage = SIMP(statut = 'o',typ = 'TXM',
784 # ------------------------------------
785 into = ["Classical EBE","Edge-based storage",],
786 defaut='Edge-based storage',
788 ),# fin Matrix_Informations
791 # ------------------------------------
792 Advection = FACT(statut = 'o',
793 # ------------------------------------
795 # ------------------------------------
796 Type_Of_Advection = FACT(statut = 'o',
797 # ------------------------------------
800 # Tres differents du dico liste de 4
801 # PNPN eclaircir les choix SVP
802 # soizic. choix 3 et 4 et 13 et 14
803 # Attention recalcul de Type_Of_Advection
804 # ------------------------------------
805 Advection_Of_U_And_V = SIMP(statut = 'o',typ = bool, defaut = True,
806 # ------------------------------------
807 fr = 'Prise en compte ou non de la convection de U et V.',
808 ang = 'The advection of U and V is taken into account or ignored.'),
810 # ------------------------------------
811 b_u_v = BLOC( condition = "Advection_Of_U_And_V == True",
812 # ------------------------------------
813 # ------------------------------------
814 Type_Of_Advection_U_And_V = SIMP(statut = 'o',typ = 'TXM',position = "global",
815 # ------------------------------------
816 into = ["Characteristics", "SUPG", "Conservative N-scheme", 'Conservative N-scheme',\
817 'Conservative PSI-scheme', 'Non conservative PSI scheme', 'Implicit non conservative N scheme',\
818 'Edge-based N-scheme'],
819 defaut = "Characteristics", ),
821 # ------------------------------------
822 b_upwind = BLOC(condition = "Type_Of_Advection_U_And_V == 'SUPG'",
823 # ------------------------------------
824 # ------------------------------------
825 Supg_Option_U_And_V = SIMP(statut = 'o', defaut = 'Modified SUPG', typ = 'TXM',
826 # ------------------------------------
827 into = ['No upwinding', 'Classical SUPG','Modified SUPG']),
829 # ------------------------------------
830 Upwind_Coefficients_Of_U_And_V = SIMP(statut = 'o',typ = 'R', defaut = 1.)
831 # ------------------------------------
835 # ------------------------------------
836 Advection_Of_H = SIMP(statut = 'o',typ = bool, defaut = True,
837 # ------------------------------------
838 fr = 'Prise en compte ou non de la convection de H.',
839 ang = 'The advection of H is taken into account or ignored.'),
841 # ------------------------------------
842 b_h = BLOC( condition = "Advection_Of_H == True",
843 # ------------------------------------
844 # ------------------------------------
845 Type_Of_Advection_H = SIMP(statut = 'o',typ = 'TXM',position = "global",
846 # ------------------------------------
847 into = ["characteristics", "SUPG", "conservative N-scheme", 'conservative N-scheme',\
848 'conservative PSI-scheme', 'non conservative PSI scheme', 'implicit non conservative N scheme',\
849 'edge-based N-scheme'],
850 defaut = "conservative PSI-scheme",),
851 # ------------------------------------
852 b_upwind_H = BLOC(condition = "Type_Of_Advection_H == 'SUPG'",
853 # ------------------------------------
854 # ------------------------------------
855 Supg_Option_H = SIMP(statut = 'o', defaut = 'Modified SUPG', typ = 'TXM',
856 # ------------------------------------
857 into = ['No upwinding', 'Classical SUPG','Modified SUPG']),
859 # ------------------------------------
860 Upwind_Coefficients_Of_H = SIMP(statut = 'o',typ = 'R', defaut = 1.)
861 # ------------------------------------
865 # ------------------------------------
866 Advection_Of_K_And_Epsilon = SIMP(statut = 'o',typ = bool, defaut = True,
867 # ------------------------------------
868 fr = 'Prise en compte ou non de la convection de Tracer.',
869 ang = 'The advection of Tracer is taken into account or ignored.'),
871 # ------------------------------------
872 b_k = BLOC( condition = "Advection_Of_K_And_Epsilon == True",
873 # ------------------------------------
874 # ------------------------------------
875 Type_Of_Advection_K_And_Epsilon = SIMP(statut = 'o',typ = 'TXM',position = "global",
876 # ------------------------------------
877 into = ["Characteristics", "SUPG", "Conservative N-scheme", 'Conservative N-scheme',\
878 'Conservative PSI-scheme', 'Non conservative PSI scheme', 'Implicit non conservative N scheme',\
879 'Edge-based N-scheme'],
880 defaut = "Characteristics",),
881 # ------------------------------------
882 b_upwind_k = BLOC(condition = "Type_Of_Advection_K_And_Epsilon == 'SUPG'",
883 # ------------------------------------
884 # ------------------------------------
885 Supg_Option_Tracers = SIMP(statut = 'o', defaut = 'Modified SUPG', typ = 'TXM',
886 # ------------------------------------
887 into = ['No upwinding', 'Classical SUPG','Modified SUPG']),
889 # ------------------------------------
890 Upwind_Coefficients_Of_K_And_Epsilon = SIMP(statut = 'o',typ = 'R', defaut = 1.)
891 # ------------------------------------
895 # ------------------------------------
896 Advection_Of_Tracers = SIMP(statut = 'o',typ = bool, defaut = True,
897 # ------------------------------------
898 fr = 'Prise en compte ou non de la convection de Tracer.',
899 ang = 'The advection of Tracer is taken into account or ignored.'),
901 # ------------------------------------
902 b_tracers = BLOC( condition = "Advection_Of_Tracers == True",
903 # ------------------------------------
904 # ------------------------------------
905 Type_Of_Advection_Tracers = SIMP(statut = 'o',typ = 'TXM',position = "global",
906 # ------------------------------------
907 into = ["Characteristics", "SUPG", "Conservative N-scheme", 'Conservative N-scheme',\
908 'Conservative PSI-scheme', 'Non conservative PSI scheme', 'Implicit non conservative N scheme',\
909 'Edge-based N-scheme'],),
910 # ------------------------------------
911 b_upwind_Tracers = BLOC(condition = "Type_Of_Advection_Tracers == 'SUPG'",
912 # ------------------------------------
913 # ------------------------------------
914 Supg_Option_K_And_Epsilon = SIMP(statut = 'o', defaut = 'Modified SUPG', typ = 'TXM',
915 # ------------------------------------
916 into = ['No upwinding', 'Classical SUPG','Modified SUPG']),
918 # ------------------------------------
919 Upwind_Coefficients_Of_Tracers = SIMP(statut = 'o',typ = 'R', defaut = 1.)
920 # ------------------------------------
921 ), # fin b_upwind_Tracers
924 # ------------------------------------
925 b_max = BLOC( condition = "(Advection_Of_Tracers == True and Type_Of_Advection_Tracers == 'Edge-based N-scheme') or (Advection_Of_K_And_Epsilon == True and Type_Of_Advection_K_And_Epsilon == 'Edge-based N-scheme') or (Advection_Of_U_And_V == True and Type_Of_Advection_U_And_V == 'Edge-based N-scheme') or ( Advection_Of_H == True and Type_Of_Advection_H == 'Edge-based N-scheme')",
926 # ------------------------------------
927 # ------------------------------------
928 Maximum_Number_Of_Iterations_For_Advection_Schemes = SIMP( statut = 'o',typ = 'I', defaut = 10 ,
929 # ------------------------------------
930 fr = 'Seulement pour schemes Edge-based N-scheme',
931 ang = 'Only for Edge-based N-scheme',),
934 # ------------------------------------
935 b_traitement = BLOC( condition = "(Advection_Of_Tracers == True and Type_Of_Advection_Tracers in ['Edge-based N-scheme','SUPG','Conservative N-scheme','Conservative PSI-scheme']) or (Advection_Of_K_And_Epsilon == True and Type_Of_Advection_K_And_Epsilon in ['Edge-based N-scheme','SUPG','Conservative N-scheme','Conservative PSI-scheme']) or (Advection_Of_U_And_V == True and Type_Of_Advection_U_And_V in ['Edge-based N-scheme','SUPG','Conservative N-scheme','Conservative PSI-scheme']) or ( Advection_Of_H == True and Type_Of_Advection_H in ['Edge-based N-scheme','SUPG','Conservative N-scheme','Conservative PSI-scheme'])",
936 # ------------------------------------
938 # ------------------------------------
939 Treatment_Of_Fluxes_At_The_Boundaries = SIMP( statut = 'o',typ = 'TXM',
940 # ------------------------------------
941 into = ["Priority to prescribed values","Priority to fluxes"],
942 fr = 'Utilise pour les schemas SUPG, PSI et N, \n\
943 si Priorité aux flux, on ne retrouve pas exactement les valeurs imposees des traceurs,mais le flux est correct',
944 ang = 'Used so far only with the SUPG, PSI and N schemes.\n\
945 if Priority to fluxes, Dirichlet prescribed values are not obeyed,but the fluxes are correct',),
947 ), # fin b_traitement
948 ), # Fin Type_Of_Advection
952 # recalculer la liste de 4
953 # Attention bloc selon le type de convection
954 # ------------------------------------
955 # SUPG = FACT(statut = 'o',
956 # ------------------------------------
957 # ------------------------------------
958 # Supg_Option_U_And_V = SIMP(statut = 'o', defaut = 'Modified SUPG', typ = 'TXM',
959 # ------------------------------------
960 # into = ['No upwinding', 'Classical SUPG','Modified SUPG']),
961 # ------------------------------------
962 # Supg_Option_H = SIMP(statut = 'o', defaut = 'Modified SUPG', typ = 'TXM',
963 # ------------------------------------
964 # into = ['No upwinding', 'Classical SUPG','Modified SUPG']),
965 # ------------------------------------
966 # Supg_Option_Tracers = SIMP(statut = 'o', defaut = 'Modified SUPG', typ = 'TXM',
967 # ------------------------------------
968 # into = ['No upwinding', 'Classical SUPG','Modified SUPG']),
969 # ------------------------------------
970 # Supg_Option_K_And_Epsilon = SIMP(statut = 'o', defaut = 'Modified SUPG', typ = 'TXM',
971 # ------------------------------------
972 # into = ['No upwinding', 'Classical SUPG','Modified SUPG']),
975 # ------------------------------------
976 Mass_Lumping_On_H = SIMP(statut = 'o',typ = 'R', defaut = 0,
977 # ------------------------------------
978 fr = 'TELEMAC offre la possibilite d''effectuer du mass-lumping sur H ou U.\n\
979 Ceci revient a ramener tout ou partie (suivant la valeur de ce coefficient) des matrices AM1 (h) ou AM2 (U) \n\
980 et AM3 (V) sur leur diagonale. Cette technique permet d''accelerer le code dans des proportions tres\n\
981 importantes et de le rendre egalement beaucoup plus stable. Cependant les solutions obtenues se trouvent lissees.\n\
982 Ce parametre fixe le taux de mass-lumping effectue sur h.',
983 ang = 'TELEMAC provides an opportunity to carry out mass-lumping either on C,H or on the velocity. \n\
984 This is equivalent to bringing the matrices AM1(h) or AM2(U) and AM3(V) wholly or partly, back onto their diagonal.\n\
985 Thanks to that technique, the code can be speeded up to a quite significant extent and it can also be made much \n\
986 more stable. The resulting solutions, however, become artificially smoothed. \n\
987 This parameter sets the extent of mass-lumping that is performed on h.'),
989 # ------------------------------------
990 Mass_Lumping_On_Velocity = SIMP(statut = 'o', typ = 'R', defaut = 0,
991 # ------------------------------------
992 fr = 'Fixe le taux de mass-lumping effectue sur la vitesse.',
993 ang = 'Sets the amount of mass-lumping that is performed on the velocity.'),
995 # ------------------------------------
996 Mass_Lumping_For_Weak_Characteristics = SIMP(statut = 'o',typ = 'R',defaut = 0,
997 # ------------------------------------
998 fr = 'Applique a la matrice de masse',
999 ang = 'To be applied to the mass matrix',),
1000 # ------------------------------------
1001 Free_Surface_Gradient_Compatibility = SIMP(statut = 'o',typ = 'R',defaut = 1.,
1002 # ------------------------------------
1003 fr = 'Des valeurs inferieures a 1 suppriment les oscillations parasites',
1004 ang = 'Values less than 1 suppress spurious oscillations'),
1006 # ------------------------------------
1007 Number_Of_Sub_Iterations_For_Non_Linearities = SIMP(statut = 'o',typ = 'I',
1008 # ------------------------------------
1010 fr = 'Permet de reactualiser, pour un meme pas de temps, les champs convecteur et propagateur \n\
1011 au cours de plusieurs sous-iterations.\n\
1012 A la premiere sous-iteration, ces champs sont donnes par C et le champ de vitesses au pas de temps precedent.\n\
1013 Aux iterations suivantes, ils sont pris egaux au champ de vitesse obtenu a la fin de la sous-iteration precedente. \n\
1014 Cette technique permet d''ameliorer la prise en compte des non linearites.',
1015 ang = 'Used for updating, within one time step, the advection and propagation field.\n\
1016 upon the first sub-iteration, \n\
1017 these fields are given by C and the velocity field in the previous time step. At subsequent iterations, \n\
1018 the results of the previous sub-iteration is used to update the advection and propagation field.\n\
1019 The non-linearities can be taken into account through this technique.',),
1024 #PNPNPN Il faut recalculer le MCSIMP Propagation
1025 # ------------------------------------
1026 Propagation = FACT(statut = 'o',
1027 # ------------------------------------
1028 # ------------------------------------
1029 Initial_Guess_For_H = SIMP(statut = 'o',typ = 'TXM',
1030 # ------------------------------------
1031 into = ['Zero', 'Previous', 'Extrapolation'],
1032 defaut = 'Previous',
1033 fr = 'Tir initial du solveur de l etape de propagation. Offre la possibilite de modifier la valeur initiale de DH,\n\
1034 accroissement de H, a chaque iteration, dans l etape de propagation en utilisant les valeurs finales de cette variable \n\
1035 aux pas de temps precedents. Ceci peut permettre daccelerer la vitesse de convergence lors de la resolution du systeme.',
1036 ang = 'Initial guess for the solver in the propagation step. Makes it possible to modify the initial value of H, \n\
1037 upon each iteration in the propagation step, by using the ultimate values this variable had in the earlier time steps.\n\
1038 Thus, the convergence can be speeded up when the system is being solved.',),
1041 # ------------------------------------
1042 Linearized_Propagation = SIMP(statut = 'o',typ = bool,defaut = False,
1043 # ------------------------------------
1044 fr = 'Permet de lineariser l''etape de propagation; \n\
1045 par exemple lors de la realisation de cas tests pour lesquels on dispose d une solution analytique dans le cas linearise.',
1046 ang = 'Provided for linearizing the propagation step; \n\
1047 e.g. when performing test-cases for which an analytical solution in the linearized case is available.' ),
1049 # ------------------------------------
1050 b_linear = BLOC(condition = "Linearized_Propagation == True ",
1051 # ------------------------------------
1052 # ------------------------------------
1053 Mean_Depth_For_Linearization = SIMP(statut = 'o',typ = 'R', defaut = 0.0, val_min = 0,
1054 # ------------------------------------
1055 fr = 'Fixe la hauteur d eau autour de laquelle s effectue la linearisation lorsque l option PROPAGATION LINEARISEE est choisie.',
1056 ang = 'Sets the water depth about which the linearization is made when the LINEARIZED PROPAGATION OPTION is selected.'),
1058 # ------------------------------------
1059 Initial_Guess_For_U = SIMP(statut = 'o',typ = 'TXM',
1060 # ------------------------------------
1061 into = ['Zero', 'Previous', 'Extrapolation'],
1062 defaut = 'Previous',
1063 fr = 'Tir initial du solveur de l etape de propagation. Offre la possibilite de modifier la valeur initiale de DH,\n\
1064 accroissement de U, a chaque iteration, dans l etape de propagation en utilisant les valeurs finales de cette variable \n\
1065 aux pas de temps precedents. Ceci peut permettre daccelerer la vitesse de convergence lors de la resolution du systeme.',
1066 ang = 'Initial guess for the solver in the propagation step. Makes it possible to modify the initial value of U, \n\
1067 upon each iteration in the propagation step, by using the ultimate values this variable had in the earlier time steps.\n\
1068 Thus, the convergence can be speeded up when the system is being solved.',),
1072 ), # fin Propagation
1075 # ------------------------------------
1076 Diffusion = FACT(statut = 'o',
1077 # ------------------------------------
1079 # ------------------------------------
1080 Diffusion_Of_Velocity = SIMP( statut='o',typ=bool,
1081 # ------------------------------------
1083 fr = 'Permet de decider si lon prend ou non en compte la diffusion des vitesses.',
1084 ang= 'Makes it possible to decide whether the diffusion of velocity (i.e. viscosity) is taken into account or not.',
1086 # ------------------------------------
1087 b_Diffu = BLOC(condition = 'Diffusion_Of_Velocity == True',
1088 # ------------------------------------
1089 # ------------------------------------
1090 Implicitation_For_Diffusion_Of_Velocity = SIMP(statut = 'o',typ = 'R',defaut = 0,
1091 # ------------------------------------
1092 fr = 'Fixe la valeur du coefficient d''implicitation sur les termes de diffusion des vitesses',
1093 ang = 'Sets the value of the implicitation coefficient for the diffusion of velocity',),
1095 # ------------------------------------
1096 Option_For_The_Diffusion_Of_Velocities = SIMP( statut='o',typ='TXM',
1097 # ------------------------------------
1099 into=['Diffusion in the form div( nu grad(U))','Diffusion in the form 1/h div ( h nu grad(U) )'],
1100 fr = '1: Diffusion de la forme div( nu grad(U) ) 2: Diffusion de la forme 1/h div ( h nu grad(U) )',
1101 ang= '1: Diffusion in the form div( nu grad(U) ) 2: Diffusion in the form 1/h div ( h nu grad(U) )',),
1105 # ------------------------------------
1106 Discretization_Implicitation = FACT(statut = 'f',
1107 # ------------------------------------
1109 # ------------------------------------
1110 Discretizations_In_Space = SIMP(statut = 'o',typ = 'TXM',
1111 # ------------------------------------
1112 into = ["Linear", "Quasi-bubble", "Quadratic"],
1113 defaut = "Linear",),
1115 # ------------------------------------
1116 Implicitation_For_Depth = SIMP(statut = 'o',typ = 'R',defaut = 0.55,
1117 # ------------------------------------
1118 fr = 'Fixe la valeur du coefficient d''implicitation sur C dans l''etape de propagation (cf. Note de principe).\n\
1119 Les valeurs inferieures a 0.5 donnent un schema instable.',
1120 ang = 'Sets the value of the implicitation coefficient for C (the celerity of waves) in the propagation step (refer to principle note).\n\
1121 Values below 0.5 result in an unstable scheme.'),
1123 # ------------------------------------
1124 Implicitation_For_Velocity = SIMP(statut = 'o',typ = 'R',defaut = 0.55,
1125 # ------------------------------------
1126 fr = 'Fixe la valeur du coefficient d''implicitation sur la vitesse dans l''etape de propagation (cf. Note de principe).\n\
1127 Les valeurs inferieures a 0.5 donnent un schema instable.',
1128 ang = 'Sets the value of the implicitation coefficient for velocity in the propagation step (refer to principle note).\n\
1129 Values below 0.5 result in an unstable condition.'),
1131 ), # fin Discretization_Implicitation
1134 # ------------------------------------
1135 Tidal=FACT(statut='f',
1136 # ------------------------------------
1137 Tidal_Flats = SIMP(statut = 'o',typ = bool,defaut = True,
1138 # ------------------------------------
1139 fr = 'permet de supprimer les tests sur les bancs decouvrants si on est certain qu''il n''y en aura pas, En cas de doute : oui',
1140 ang = 'When no,the specific treatments for tidal flats are by-passed. This spares time, but of course you must be sure that you have no tidal flats'),
1142 # ------------------------------------
1143 b_tidal_flats = BLOC(condition = 'Tidal_Flats == True',
1144 # ------------------------------------
1145 # ------------------------------------
1146 Option_For_The_Treatment_Of_Tidal_Flats = SIMP(statut = 'o',typ = 'TXM',
1147 # ------------------------------------
1148 into = ["Equations solved everywhere with correction on tidal flats", "Dry elements frozen", "1 but with porosity (defina method)",],
1149 defaut="Equations solved everywhere with correction on tidal flats",),
1151 # ------------------------------------
1152 b_option_tidal_flats = BLOC(condition = 'Option_For_The_Treatment_Of_Tidal_Flats == "Equations solved everywhere with correction on tidal flats"',
1153 # ------------------------------------
1154 # ------------------------------------
1155 Treatment_Of_Negative_Depths = SIMP( statut = 'o',typ = 'TXM',
1156 # ------------------------------------
1157 into = [ 'No treatment', 'Smoothing', 'Flux control'],
1158 defaut = 'Smoothing' ,),
1159 ), # fin bloc b_option_tidal_flats
1161 # ------------------------------------
1162 Threshold_For_Negative_Depths = SIMP( statut = 'o',typ = 'R', defaut = 0.0 ,
1163 # ------------------------------------
1164 fr = 'En dessous du seuil, les hauteurs negatives sont lissees',
1165 ang = 'Below the threshold the negative depths are smoothed',),
1167 # ------------------------------------
1168 Threshold_Depth_For_Receding_Procedure = SIMP(statut = 'o',typ = 'R',defaut = 0 ,
1169 # ------------------------------------
1170 fr = 'Si > 0., declenche la procedure de ressuyage qui evite le franchissement parasite des digues mal discretisees',
1171 ang = 'If > 0., will trigger the receding procedure that avoids overwhelming of dykes which are too loosely discretised ',),
1174 # ------------------------------------
1175 H_Clipping = SIMP(statut = 'o',typ = bool,defaut = False,
1176 # ------------------------------------
1177 fr = 'Determine si on desire ou non limiter par valeur inferieure la hauteur d eau H (dans le cas des bancs decouvrants par exemple).',
1178 ang = 'Determines whether limiting the water depth H by a lower value desirable or not. (for instance in the case of tidal flats)\n\
1179 This key-word may have an influence on mass conservation since the truncation of depth is equivalent to adding mass.',),
1181 # ------------------------------------
1182 b_clipping = BLOC(condition = 'H_Clipping == True',
1183 # ------------------------------------
1184 # ------------------------------------
1185 Minimum_Value_Of_Depth = SIMP( statut = 'o',typ = 'R', defaut = 0.0 ,
1186 # ------------------------------------
1187 fr = 'Fixe la valeur minimale de a lorsque loption CLIPPING DE H est activee.',
1188 ang = 'Sets the minimum H value when option H CLIPPING is implemented. Not fully implemented.',),
1190 ), # fin bloc b_tidal_flats
1193 # ------------------------------------
1195 # ------------------------------------
1197 # ------------------------------------
1198 Newmark_Time_Integration_Coefficient = SIMP( statut = 'o',typ = 'TXM',
1199 # ------------------------------------
1200 defaut = "Euler explicite",
1201 into = ["Euler explicite","Order 2 in time"],),
1203 # ------------------------------------
1204 Option_For_Characteristics = SIMP( statut = 'o',typ = 'TXM',
1205 # ------------------------------------
1207 into = ['Strong','Weak',],),
1212 )# fin NUMERICAL_PARAMETERS
1214 # -----------------------------------------------------------------------
1215 PHYSICAL_PARAMETERS = PROC(nom = "PHYSICAL_PARAMETERS",op = None,
1216 # -----------------------------------------------------------------------
1217 UIinfo = { "groupes" : ( "CACHE", )},
1218 # ------------------------------------
1219 Friction_Setting = FACT(statut = 'o',
1220 # ------------------------------------
1221 # ------------------------------------
1222 Friction_Data_File = SIMP( statut = 'o',
1223 # ------------------------------------
1224 typ = ('Fichier', ';;All Files (*)'),
1225 fr = 'fichier de donnees pour le frottement',
1226 ang = 'friction data file',),
1228 # ------------------------------------
1229 Depth_In_Friction_Terms = SIMP( statut = 'o',typ = 'TXM',
1230 # ------------------------------------
1232 into = ("Nodal", "Average"),),
1234 # ------------------------------------
1235 Law_Of_Bottom_Friction = SIMP( statut = 'o',typ = 'TXM',
1236 # ------------------------------------
1237 defaut = 'No friction' ,
1238 into = ('No friction', 'Haaland', 'Chezy', 'Strickler', 'Manning', 'Nikuradse','Log law','Colebrooke_white'),
1239 fr = 'selectionne le type de formulation utilisee pour le calcul du frottement sur le fond.',
1240 ang = 'Selects the type of formulation used for the bottom friction.',),
1242 # ------------------------------------
1243 b_Law_Friction = BLOC(condition = "Law_Of_Bottom_Friction!= 'No friction'",
1244 # ------------------------------------
1245 # ------------------------------------
1246 Friction_Coefficient = SIMP( statut = 'o',typ = 'R',
1247 # ------------------------------------
1249 fr = 'Fixe la valeur du coefficient de frottement pour la formulation choisie. \
1250 Attention, la signification de ce chiffre varie suivant la formule choisie : \
1251 1 : coefficient lineaire 2 : coefficient de Chezy 3 : coefficient de Strickler \
1252 4 : coefficient de Manning 5 : hauteur de rugosite de Nikuradse',
1253 ang = 'Sets the value of the friction coefficient for the selected formulation. \
1254 It is noteworthy that the meaning of this figure changes according to the selected formula (Chezy, Strickler, etc.) : \
1255 1 : linear coefficient 2 : Chezy coefficient 3 : Strickler coefficient 4 : Manning coefficient 5 : Nikuradse grain size',),
1256 ), # Fin b_Law_Friction
1258 # ------------------------------------
1259 b_Colebrooke_White = BLOC(condition = "Law_Of_Bottom_Friction == 'Colebrooke_white'",
1260 # ------------------------------------
1261 # ------------------------------------
1262 Manning_Default_Value_For_Colebrook_White_Law = SIMP( statut = 'o',typ = 'R',
1263 # ------------------------------------
1265 fr = 'valeur par defaut du manning pour la loi de frottement de Colebrook-White ',
1266 ang = 'Manning default value for the friction law of Colebrook-White ',),
1267 ), # Fin b_Colebrooke_White
1269 # ------------------------------------
1270 Non_Submerged_Vegetation_Friction = SIMP( statut = 'o',typ = bool,
1271 # ------------------------------------
1273 fr = 'calcul du frottement du a la vegetation non submergee',
1274 ang = 'friction calculation of the non-submerged vegetation',),
1276 # ------------------------------------
1277 b_Non_Sub = BLOC(condition = ' Non_submerged_Vegetation_Friction == True',
1278 # ------------------------------------
1279 # ------------------------------------
1280 Diameter_Of_Roughness_Elements = SIMP( statut = 'o',typ = 'R',
1281 # ------------------------------------
1283 fr = 'diametre des elements de frottements',
1284 ang = 'diameter of roughness element',),
1286 # ------------------------------------
1287 Spacing_Of_Roughness_Elements = SIMP( statut = 'o',typ = 'R',
1288 # ------------------------------------
1290 fr = 'espacement des elements de frottement',
1291 ang = 'spacing of rouhness element',),
1294 # ------------------------------------
1295 Law_Of_Friction_On_Lateral_Boundaries = SIMP( statut = 'o',typ = 'TXM',
1296 # ------------------------------------
1297 defaut = "No friction" ,
1298 into = ("No friction", "Haaland", "Chezy", "Strickler", "Manning", "Nikuradse", "Log law", "Colebrook-white"),
1299 fr = 'selectionne le type de formulation utilisee pour le calcul du frottement sur les parois laterales.',
1300 ang = 'Selects the type of formulation used for the friction on lateral boundaries.',),
1303 # ------------------------------------
1304 b_Fric = BLOC(condition = 'Law_Of_Friction_On_Lateral_Boundaries != "No friction"',
1305 # ------------------------------------
1307 # PNPNPN soizic ?Ne faut-il pas un bloc sur Law_Of_Friction_On_Lateral_Boundaries
1308 # ------------------------------------
1309 Roughness_Coefficient_Of_Boundaries = SIMP( statut = 'o',typ = 'R',
1310 # ------------------------------------
1312 fr = 'Fixe la valeur du coefficient de frottement sur les frontieres solides avec un regime turbulent rugueux\n\
1313 sur les bords du domaine. meme convention que pour le coefficient de frottement',
1314 ang = 'Sets the value of the friction coefficient of the solid boundary with the bed roughness option. Same meaning than friction coefficient',),
1316 # ------------------------------------
1317 Maximum_Number_Of_Friction_Domains = SIMP( statut = 'o',typ = 'I',
1318 # ------------------------------------
1320 fr = 'nombre maximal de zones pouvant etre definies pour le frottement. Peut etre augmente si necessaire',
1321 ang = 'maximal number of zones defined for the friction. Could be increased if needed',),
1324 # ------------------------------------
1325 Definition_Of_Zones = SIMP(typ = bool, statut = 'o', defaut = False,
1326 # ------------------------------------
1327 fr = 'Declenche l''appel a def_zones, pour donner un numero de zone a chaque point',
1328 ang = 'Triggers the call to def_zones to give a zone number to every point',),
1330 # ------------------------------------
1331 b_def_zone = BLOC (condition = 'Definition_Of_Zones == True',
1332 # ------------------------------------
1333 # ------------------------------------
1334 Consigne = SIMP(statut = "o",homo = 'information',typ = "TXM", defaut = "complete DEF_ZONES subroutine"),
1335 # ------------------------------------
1338 ), # Fin du bloc Friction
1339 # ------------------------------------
1340 Meteorology = FACT(statut = 'f',
1341 # ------------------------------------
1343 # ------------------------------------
1344 Wind = SIMP(statut = 'o',typ = bool,defaut = False,
1345 # ------------------------------------
1346 fr = 'Prise en compte ou non des effets du vent.',
1347 ang = 'Determines whether the wind effects are to be taken into account or not.'),
1349 # ------------------------------------
1350 b_Wind = BLOC(condition = "Wind == True",
1351 # ------------------------------------
1352 # ------------------------------------
1353 Wind_Velocity_Along_X = SIMP(statut = 'o',typ = 'R', defaut = 0.,
1354 # ------------------------------------
1355 fr = 'Composante de la vitesse du vent suivant l''axe des x (m/s).',
1356 ang = 'Wind velocity, component along x axis (m/s).',),
1358 # ------------------------------------
1359 Wind_Velocity_Along_Y = SIMP(statut = 'o',typ = 'R',defaut = 0.,
1360 # ------------------------------------
1361 fr = 'Composante de la vitesse du vent suivant l''axe des y (m/s).',
1362 ang = 'Wind velocity, component along y axis (m/s).',),
1364 # ------------------------------------
1365 Threshold_Depth_For_Wind = SIMP(statut = 'o',typ = 'R',defaut = 0.,
1366 # ------------------------------------
1367 fr = 'Retire la force due au vent dans les petites profondeurs',
1368 ang = 'Wind is not taken into account for small depths' ),
1370 # ------------------------------------
1371 Coefficient_Of_Wind_Influence = SIMP( statut = 'o',typ = 'R', defaut = 0.0 ,
1372 # ------------------------------------
1373 fr = 'Fixe la valeur du coefficient d entrainement du vent (cf. Note de principe).',
1374 ang = 'Sets the value of the wind driving coefficient. Refer to principle note.',),
1376 # ------------------------------------
1377 Option_For_Wind = SIMP( statut = 'o',typ = 'TXM', defaut = 0 ,
1378 # ------------------------------------
1379 into = ["No wind","Constant in time and space","Variable in time","Variable in time and space"],
1380 fr = 'donne les options pour introduire le vent',
1381 ang = 'gives option for managing the wind'),
1383 # ------------------------------------
1384 file_For_wind = BLOC (condition = 'Option_For_Wind == "Variable in time" or Option_For_Wind == "Variable in time and space"',
1385 # ------------------------------------
1386 # ------------------------------------
1387 Consigne = SIMP(statut = "o",homo = 'information',typ = "TXM",
1388 # ------------------------------------
1389 defaut = "give formated file 3"),
1390 ), # fin bloc file_For_wind
1392 # ------------------------------------
1393 speed_For_wind = BLOC (condition = 'Option_For_Wind == "Constant in time and space"',
1394 # ------------------------------------
1395 # ------------------------------------
1396 Speed_And_Direction_Of_Wind = SIMP( statut = 'o', defaut = (0.0, 0.0) ,
1397 # ------------------------------------
1398 typ = Tuple(2),validators = VerifTypeTuple(('R','R')),
1399 fr = 'Donne la vitesse et la direction (en degres de 0 a 360, 0 etant y = 0 et x = +inf) du vent',
1400 ang = 'gives the speed and direction (degre (from 0 to 360), 0 given y = 0 anx x = +infinity)',),
1405 # ------------------------------------
1406 Air_Pressure = SIMP(statut = 'o',typ = bool, defaut = False,
1407 # ------------------------------------
1408 fr = 'Permet de decider si l''on prend ou non en compte l''influence d''un champ de pression.',
1409 ang = 'Provided to decide whether the influence of an atmosphere field is taken into account or not.'),
1411 # ------------------------------------
1412 b_air = BLOC(condition = "Air_Pressure == True",
1413 # ------------------------------------
1414 # ------------------------------------
1415 Value_Of_Atmospheric_Pressure = SIMP( statut = 'o',typ = 'R',
1416 # ------------------------------------
1418 fr = 'donne la valeur de la pression atmospherique lorsquelle est constante en temps et en espace',
1419 ang = 'gives the value of atmospheric pressure when it is contant in time and space',),
1422 # ------------------------------------
1423 Rain_Or_Evaporation = SIMP(statut = 'o',typ = bool,
1424 # ------------------------------------
1426 fr = 'Pour ajouter un apport ou une perte d''eau en surface.',
1427 ang = 'to add or remove water at the free surface. ',),
1429 # -----------------------------------
1430 b_Rain = BLOC(condition = "Rain_Or_Evaporation == True",
1431 # ------------------------------------
1432 # ------------------------------------
1433 Rain_Or_Evaporation_In_Mm_Per_Day = SIMP(statut = 'o',typ = 'I',defaut = 0.),
1434 # ------------------------------------
1437 ), # fin Meteorology
1439 # ------------------------------------
1440 Wave = FACT(statut = 'f',
1441 # ------------------------------------
1443 # ------------------------------------
1444 Wave_Driven_Currents = SIMP(statut = 'o',
1445 # ------------------------------------
1446 typ = bool, defaut = False,
1447 fr = 'Active la prise en compte des courants de houle',
1448 ang = 'Wave driven currents are taken into account.'),
1450 # ------------------------------------
1451 b_Wave = BLOC(condition = "Wave_Driven_Currents == True",
1452 # ------------------------------------
1453 # ------------------------------------
1454 Record_Number_In_Wave_File = SIMP(statut = 'o',typ = 'I', defaut = 1,
1455 # ------------------------------------
1456 fr = 'Numero d enregistrement dans le fichier des courants de houle',
1457 ang = 'Record number to read in the wave driven currents file'),
1463 # ------------------------------------
1464 Parameters_Estimation = FACT(statut = 'f',
1465 # ------------------------------------
1466 # ------------------------------------
1467 Parameter_Estimation = SIMP( statut = 'o',typ = 'TXM', into = ["Friction","Frottement","Steady"],
1468 # ------------------------------------
1469 fr = 'Liste des parametres a estimer',
1470 ang = 'List of parameter to be estimated',),
1472 # ------------------------------------
1473 Identification_Method = SIMP( statut = 'o',typ = 'TXM',
1474 # ------------------------------------
1475 into = ["List of tests", "Gradient simple", "Conj gradient", "Lagrange interp."],
1476 defaut = 'GRadient simple',),
1478 # ------------------------------------
1479 Maximum_Number_Of_Iterations_For_Identification = SIMP(statut = 'o',typ = 'I',defaut = 20,
1480 # ------------------------------------
1481 fr = 'chaque iteration comprend au moins un calcul direct et un calcul adjoint',
1482 ang = 'every iteration implies at least a direct and an adjoint computation', ),
1484 # ------------------------------------
1485 Cost_Function = SIMP(statut = "f",typ = 'TXM',
1486 # ------------------------------------
1487 defaut = 'Computed with h, u , v',
1488 into = ['Computed with h, u , v', 'Computed with c, u , v'],),
1490 # ------------------------------------
1491 Tolerances_For_Identification = FACT( statut = 'o',
1492 # ------------------------------------
1493 # PNPNPN recalculer en liste de 4 reels
1494 # ------------------------------------
1495 Tolerance_For_H = SIMP( statut = 'o',typ = 'R', defaut=1.E-3,
1496 # ------------------------------------
1497 fr = "precision absolue sur H",
1498 ang = "absolute precision on H",),
1499 # ------------------------------------
1500 Tolerance_For_U = SIMP( statut = 'o',typ = 'R', defaut=1.E-3,
1501 # ------------------------------------
1502 fr = "precision absolue sur U",
1503 ang = "absolute precision on U",),
1504 # ------------------------------------
1505 Tolerance_For_V = SIMP( statut = 'o',typ = 'R', defaut=1.E-3,
1506 # ------------------------------------
1507 fr = "precision absolue sur V",
1508 ang = "absolute precision on V",),
1509 # ------------------------------------
1510 Tolerance_For_cout = SIMP( statut = 'o',typ = 'R', defaut=1.E-4,
1511 # ------------------------------------
1512 fr = "precision relative sur la fonction cout",
1513 ang = "relative precision on the cost function",),
1514 ),# fin Tolerances_For_Identification
1516 ), # fin fact Parameters_Estimation
1518 # ------------------------------------
1519 Sources = FACT( statut = 'f',
1520 # ------------------------------------
1521 # ------------------------------------
1522 Number_Of_Sources = SIMP( statut = 'o',typ = 'I', defaut = 0 ,),
1523 # ------------------------------------
1524 # Attention a la sortie a reformatter. voir page 68 du user manuel V7
1526 # ------------------------------------
1527 sources_exists = BLOC(condition = "Number_Of_Sources!= 0",
1528 # ------------------------------------
1530 # ------------------------------------
1531 Sources_File = SIMP( statut = 'o',
1532 # ------------------------------------
1533 typ = ('Fichier', 'All Files (*)',),
1534 fr = 'Nom du fichier contenant les informations variables en temps des sources',
1535 ang = 'Name of the file containing time-dependent information on sources',),
1537 #PNPNPNPN saisir autant de source que le nombre
1538 # ------------------------------------
1539 Source = FACT(statut = 'o',
1540 # ------------------------------------
1542 # ------------------------------------
1543 Abscissae_Of_Sources = SIMP( statut = 'o',
1544 # ------------------------------------
1545 typ = Tuple(2),validators = VerifTypeTuple(('R','R')),
1546 fr = 'Valeurs des abscisses des sources de debit et de traceur.',
1547 ang = 'abscissae of sources of flowrate and/or tracer',),
1549 # ------------------------------------
1550 Ordinates_Of_Sources = SIMP( statut = 'o',
1551 # ------------------------------------
1552 typ = Tuple(2),validators = VerifTypeTuple(('R','R')),
1553 fr = 'Valeurs des ordonnees des sources de debit et de traceur.',
1554 ang = 'ordinates of sources of flowrate and/or tracer',),
1556 # ------------------------------------
1557 Water_Discharge_Of_Sources = SIMP( statut = 'o',
1558 # ------------------------------------
1559 typ = Tuple(2),validators = VerifTypeTuple(('R','R')),
1560 fr = 'Valeurs des debits des sources.',
1561 ang = 'values of water discharge of sources',),
1563 # ------------------------------------
1564 Velocities_Of_The_Sources_Along_X = SIMP( statut = 'f',
1565 # ------------------------------------
1566 typ = Tuple(2),validators = VerifTypeTuple(('R','R')),
1567 fr = 'Vitesses du courant a chacune des sources. Si elles ne sont pas donnees, on considere que la vitesse est celle du courant',
1568 ang = 'Velocities at the sources. If they are not given, the velocity of the flow at this location is taken',),
1570 # ------------------------------------
1571 Velocities_Of_The_Sources_Along_Y = SIMP( statut = 'f',
1572 # ------------------------------------
1573 typ = Tuple(2),validators = VerifTypeTuple(('R','R')),
1574 fr = 'Vitesses du courant a chacune des sources',
1575 ang = 'Velocities at the sources',),
1577 ), # Fin du Fact Source
1579 # ------------------------------------
1580 Type_Of_Sources = SIMP(statut = 'o',typ = 'TXM',into = ["Normal","Dirac"],
1581 # ------------------------------------
1582 fr = 'Source portee par une base elements finis Source portee par une fonction de Dirac',
1583 ang = 'Source term multiplied by a finite element basis, Source term multiplied by a Dirac function',),
1585 ),#fin bloc source - exits
1586 ),#fin MC source - exits
1589 # ------------------------------------
1590 Coriolis_Settings = FACT(statut = 'f',
1591 # ------------------------------------
1592 # ------------------------------------
1593 Coriolis = SIMP( statut='o',typ=bool,
1594 # ------------------------------------
1596 fr = 'Prise en compte ou non de la force de Coriolis.',
1597 ang= 'The Coriolis force is taken into account or ignored.',),
1599 # -------------------------------------------------------
1600 Coriolis_Coefficient = SIMP( statut='o',typ='R',
1601 # -------------------------------------------------------
1603 fr = 'Fixe la valeur du coefficient de la force de Coriolis. Celui-ci doit etre calcule en fonction de la latitude l \n\
1604 par la formule FCOR = 2w sin(l) , w etant la vitesse de rotation de la terre. w = 7.27 10-5 rad/s \n\
1605 Les composantes de la force de Coriolis sont alors : FU = FCOR x V FV = - FCOR x U',
1606 ang= 'Sets the value of the Coriolis force coefficient, in cartesian coordinates. This coefficient,\n\
1607 denoted FCOR in the code, should be equal to 2 w sin(l)d where w denotes the earth angular speed of rotation and l the latitude. \n\
1608 w = 7.27 10-5 rad/sec The Coriolis force components are then: FU = FCOR x V, FV = -FCOR x U In spherical coordinates, the latitudes are known',),
1609 ), #fin Coriolis_Settings
1613 # ------------------------------------
1614 Various = FACT( statut = 'f',
1615 # ------------------------------------
1616 # ------------------------------------
1617 Water_Density = SIMP(statut = 'o',typ = 'R',defaut = 1000.,
1618 # ------------------------------------
1619 fr = 'Fixe la valeur de la masse volumique de l eau.',
1620 ang = 'set the value of water density',
1623 # ------------------------------------
1624 Gravity_Acceleration = SIMP(statut = 'o',typ = 'R',defaut = 9.81,
1625 # ------------------------------------
1626 fr = 'Fixe la valeur de l acceleration de la pesanteur.',
1627 ang = 'Set the value of the acceleration due to gravity.',
1630 # ------------------------------------
1631 Vertical_Structures = SIMP(statut = 'o',typ = bool,defaut = False,
1632 # ------------------------------------
1633 fr = 'Prise en compte de la force de trainee de structures verticales',
1634 ang = 'drag forces from vertical structures are taken into account',),
1636 # ------------------------------------
1637 maskob = BLOC (condition = 'Vertical_Structures == True',
1638 # ------------------------------------
1639 # ------------------------------------
1640 Consigne = SIMP(statut = "o",homo = 'information',typ = "TXM",
1641 # ------------------------------------
1642 defaut = "subroutine DRAGFO must then be implemented"),
1646 # -----------------------------------------------------------------------
1647 Secondary_Currents_Settings = FACT( statut='f',
1648 # -----------------------------------------------------------------------
1649 # -----------------------------------------------------------------------
1650 Secondary_Currents = SIMP( statut='o',typ=bool,
1651 # -----------------------------------------------------------------------
1653 fr = 'Pour prendre en compte les courants secondaires',
1654 ang= 'Using the parametrisation for secondary currents',
1657 # -----------------------------------------------------------------------
1658 b_currents_exists = BLOC(condition = "Secondary_Currents == True",
1659 # -----------------------------------------------------------------------
1660 # -----------------------------------------------------------------------
1661 Production_Coefficient_For_Secondary_Currents = SIMP( statut='o',typ='R',
1662 # -----------------------------------------------------------------------
1664 fr = 'Une constante dans les termes de creation de Omega',
1665 ang= 'A constant in the production terms of Omega',),
1667 # -----------------------------------------------------------------------
1668 Dissipation_Coefficient_For_Secondary_Currents = SIMP( statut='o',typ='R',
1669 # -----------------------------------------------------------------------
1671 fr = 'Coefficient de dissipation de Omega',
1672 ang= 'Coefficient of dissipation term of Omega',),
1674 ), # fin b_currents_exists
1675 ), # fin Secondary_Currents_Settings
1677 # ------------------------------------
1678 Tsunami = FACT(statut = 'f',
1679 # ------------------------------------
1680 # -------------------------------------------------------
1681 Option_For_Tsunami_Generation = SIMP( statut='o',typ='I', defaut=0 ,
1682 # -------------------------------------------------------
1686 # -------------------------------------------------------
1687 Physical_Characteristics_Of_The_Tsunami = SIMP( statut='o',typ='R',
1688 # -------------------------------------------------------
1690 defaut=(100.0, 210000.0, 75000.0, 13.6, 81.0, 41.0, 110.0, 0.0, 0.0, 3.0) ,
1695 )# fin PHYSICAL_PARAMETERS
1697 # -----------------------------------------------------------------------
1698 OUTPUT_FILES = PROC(nom = "OUTPUT_FILES",op = None,
1699 # -----------------------------------------------------------------------
1701 # ------------------------------------
1702 Graphic_And_Listing_Printouts = FACT(statut = 'f',
1703 # ------------------------------------
1704 # ------------------------------------
1705 Variables_For_Graphic_Printouts = SIMP(statut = 'o',max = "**", typ = 'TXM',
1706 # ------------------------------------
1707 into=[ "Velocity along X axis (m/s)", "Velocity along Y axis (m/s)", "Wave celerity (m/s)", "Water depth (m)",
1708 "Free surface elevation (m)", "Bottom elevation (m)", "Froude number ", "Scalar flowrate of fluid (m2/s)",
1709 "Tracer 1 etc. ", "Turbulent kinetic energy in K-Epsilon model (J/kg)", "Dissipation of turbulent energy (W/kg)",
1710 "Turbulent viscosity of K-Epsilon model (m2/s)", "Flowrate along X axis (m2/s)", "Flowrate along Y axis (m2/s)",
1711 "Scalar velocity (m/s)", "Wind along X axis (m/s)", "Wind along Y axis (m/s)", "Air pressure (Pa)",
1712 "Friction coefficient", "Drift along X (m)", "Drift along Y (m)", "Courant number ", "Supplementary variable N ",
1713 "Supplementary variable O ", "Supplementary variable R ", "Supplementary variable Z ", "Maximum elevation",
1714 "Time of maximum elevation ", "Maximum velocity", "Time of maximum velocity", "Friction velocity "],
1715 homo="SansOrdreNiDoublon"),
1717 # ------------------------------------
1718 Graphic_Printout_Period = SIMP(statut = 'o', typ = 'I',defaut = 1,
1719 # ------------------------------------
1720 fr = 'Determine la periode en nombre de pas de temps d''impression des VARIABLES POUR LES SORTIES GRAPHIQUES \n\
1721 dans le FICHIER DES RESULTATS.',
1722 ang = 'Determines, in number of time steps, the printout period for the VARIABLES FOR GRAPHIC PRINTOUTS in the RESULTS FILE.' ,),
1724 # ------------------------------------
1725 Number_Of_First_Time_Step_For_Graphic_Printouts = SIMP(statut = 'o', typ = 'I',defaut = 1,
1726 # ------------------------------------
1727 fr = 'Determine le nombre de pas de temps a partir duquel debute l''ecriture des resultats dans le listing.',
1728 ang = 'Determines the number of time steps after which the results are first written into the listing.'),
1731 # ------------------------------------
1732 Results_File = SIMP( statut = 'o',
1733 # ------------------------------------
1734 typ = ('Fichier', 'All Files (*)',),
1735 fr = 'Nom du fichier dans lequel sont ecrits les resultats du calcul avec la periodicite donnee PERIODE POUR LES SORTIES GRAPHIQUES.',
1736 ang = 'Name of the file into which the computation results shall be written, the periodicity being given by GRAPHIC PRINTOUT PERIOD.',),
1738 # ------------------------------------
1739 Results_File_Format = SIMP( statut = 'o',typ = 'TXM',into = ['Serafin','MED','SerafinD'], defaut = 'Serafin',
1740 # ------------------------------------
1741 fr = 'Format du fichier de resultats. Les valeurs possibles sont : \n\
1742 - SERAFIN : format standard simple precision pour Telemac; \n\
1743 - SERAFIND: format standard double precision pour Telemac; \n\
1744 - MED : format MED base sur HDF5' ,
1745 ang = 'Results file format. Possible values are:\n \
1746 - SERAFIN : classical single precision format in Telemac;\n\
1747 - SERAFIND: classical double precision format in Telemac; \n\
1748 - MED : MED format based on HDF5' ,
1751 # ------------------------------------
1752 Listing_Printout_Period = SIMP(statut = 'o', typ = 'I',defaut = 1,
1753 # ------------------------------------
1754 fr = 'Determine la periode en nombre de pas de temps d''impression des variables',
1755 ang = 'Determines, in number of time steps, the printout period for the variables',),
1757 # ------------------------------------
1758 Listing_Printout = SIMP( statut='o',typ=bool, defaut=True ,
1759 # ------------------------------------
1760 fr = 'Sortie des resultats sur support papier. Si on met False, le listing ne contient que lentete et la mention FIN NORMALE DU PROGRAMME : La Valeur False est a eviter',
1761 ang= 'Result printout on hard copy. When NO is selected, the listing only includes the heading and the phrase "NORMAL END OF PROGRAM" In addition, the options MASS BALANCE and VALIDATION are inhibited. Value False Not recommended for use.',
1764 # ------------------------------------
1765 Variables_To_Be_Printed = SIMP(statut = 'o',max = "**", typ = 'TXM',
1766 # ------------------------------------
1767 into = [ "Velocity along X axis (m/s)", "Velocity along Y axis (m/s)", "Wave celerity (m/s)", "Water depth (m)",
1768 "Free surface elevation (m)", "Bottom elevation (m)", "Froude number", "Scalar flowrate of fluid (m2/s)",
1769 "Tracer", "Turbulent kinetic energy in K-Epsilon model (J/kg)", "Dissipation of turbulent energy (W/kg)",
1770 "Turbulent viscosity of K-Epsilon model (m2/s)", "Flowrate along x axis (m2/s)", "Flowrate along y axis (m2/s)",
1771 "Scalar velocity (m/s)", "Wind along x axis (m/s)", "Wind along y axis (m/s)", "Air pressure (Pa)",
1772 "Friction coefficient", "Drift along x (m)", "Drift along y (m)", "Courant number",
1773 "Supplementary variable N", "Supplementary variable O", "Supplementary variable R", "Supplementary variable Z"]
1774 ,homo="SansOrdreNiDoublon"),
1776 ),# fin Listing_Graphic_Printouts
1778 # ------------------------------------
1779 Formatted_Results_File = SIMP( statut = 'f',
1780 # ------------------------------------
1781 typ = ('Fichier','All Files (*)',),
1782 fr = 'Fichier de resultats formate mis a la disposition de l utilisateur. \
1783 Les resultats a placer dans ce fichier seront a ecrire sur le canal 29.',
1784 ang = 'Formatted file of results made available to the user. \
1785 The results to be entered into this file shall be written on channel 29.',),
1788 # ------------------------------------
1789 Binary_Results_File = SIMP( statut = 'f',
1790 # ------------------------------------
1791 typ = ('Fichier', ';;All Files (*)',),
1792 fr = "Fichier de resultats code en binaire mis a la disposition de l'utilisateur.\n\
1793 Les resultats a placer dans ce fichier seront a ecrire sur le canal 28.",
1794 ang = "Additional binary-coded result file made available to the user. \n\
1795 The results to be entered into this file shall be written on channel 28.",),
1798 # ------------------------------------
1799 Output_Of_Initial_Conditions = SIMP(typ = bool, statut = 'o',
1800 # ------------------------------------
1802 fr = 'Si Vrai, impression des conditions initiales dans les resultats',
1803 ang = 'If True, output of initial conditions in the results'),
1805 # ------------------------------------
1806 Number_Of_Private_Arrays = SIMP( statut='o',typ='I',
1807 # ------------------------------------
1809 fr = 'Nombre de tableaux mis a disposition de l utilisateur',
1810 ang= 'Number of arrays for own user programming',
1814 # ------------------------------------
1815 Information_About_Solver = SIMP(typ = bool, statut = 'f',
1816 # ------------------------------------
1818 fr = "Si vrai, Donne a chaque pas de temps le nombre d'iterations necessaires a la convergence du solveur de l'etape de propagation.",
1819 ang = "if True, prints the number of iterations that have been necessary to get the solution of the linear system.",),
1821 # ------------------------------------
1822 Mass_Balance = SIMP( statut='o',typ=bool,
1823 # ------------------------------------
1825 fr = 'Determine si l on effectue ou non le bilan de masse sur le domaine. Cette procedure calcule a chaque pas de temps : \n\
1826 - les flux aux entrees et sorties du domaine, - le flux global a travers lensemble des parois du domaine (liquides ou solides) \n\
1827 - l erreur relative sur la masse pour ce pas de temps.\n\
1828 En fin de listing, on trouve l erreur relative sur la masse pour l ensemble du calcul.\n\
1829 Il ne sagit que dun calcul indicatif car il nexiste pas dexpression compatible du debit en formulation c,u,v.',
1831 ang= 'Determines whether a check of the mass-balance over the domain is mader or not.\n\
1832 This procedures computes the following at each time step: the domain inflows and outflows, the overall flow across all the boundaries,\n\
1833 the relative error in the mass for that time step. The relative error in the mass over the whole computation can be found at the end of the listing.',
1836 # ------------------------------------
1837 Controls = FACT( statut='f',
1838 # ------------------------------------
1839 # ------------------------------------
1840 Control_Sections = SIMP(statut = 'f',typ = Tuple(2),validators = VerifTypeTuple(('I','I')),
1841 # ------------------------------------
1842 fr = 'Couples de points (numeros globaux dans le maillage) entre lesquels les debits instantanes et cumules seront donnes.',
1843 ang = 'Couples of points (global numbers in the mesh) defining sections where the instantaneous and cumulated discharges will be given',),
1845 # ------------------------------------
1846 Printing_Cumulated_Flowrates = SIMP( statut = 'o',typ = bool, defaut = False ,
1847 # ------------------------------------
1848 fr = 'impression du flux cumule a travers les sections de controle',
1849 ang = 'printing the cumulated flowrates through control sections',),
1851 # ------------------------------------
1852 Compatible_Computation_Of_Fluxes = SIMP( statut = 'o',typ = bool, defaut = False ,
1853 # ------------------------------------
1854 fr = 'flux a travers les sections de controle, calcul compatible avec l impermeabilite sous forme faible',
1855 ang = 'flowrates through control sections, computation compatible with the weak formulation of no-flux boundary condition',),
1857 # ------------------------------------
1858 Sections_Input_File = SIMP( statut = 'f', typ = ('Fichier', 'All Files (*)'),
1859 # ------------------------------------
1860 fr = 'sections input file, partitioned',
1861 ang = 'sections input file, partitioned',),
1863 # ------------------------------------
1864 Sections_Output_File = SIMP( statut = 'f', typ = ('Fichier', 'All Files (*)'),
1865 # ------------------------------------
1866 fr = 'sections output file, written by the master',
1867 ang = 'sections output file, written by the master',),
1870 # ------------------------------------
1871 Fourier = FACT(statut = 'f',
1872 # ------------------------------------
1873 # ------------------------------------
1874 Fourier_Analysis_Periods = SIMP( statut='o',
1875 # ------------------------------------
1876 max='**', typ = 'R',
1877 fr = 'Liste des periodes que lon veut analyser',
1878 ang= 'List of periods to be analysed',),
1880 # ------------------------------------
1881 Time_Range_For_Fourier_Analysis = SIMP( statut='o',
1882 # ------------------------------------
1883 typ = Tuple(2), validators = VerifTypeTuple(('R','R')),
1885 fr = 'Pour le calcul du marnage et de la phase de la maree',
1886 ang= 'For computing tidal range and phase of tide',
1889 # ------------------------------------
1890 List_Of_Points = SIMP( statut='o',
1891 # ------------------------------------
1892 typ = Tuple(2), validators = VerifTypeTuple(('I','I')),
1893 fr = 'Liste de points remarquables pour les impressions',
1894 ang= 'List of remarkable points for printouts',),
1896 # ------------------------------------
1897 Names_Of_Points = SIMP( statut='o',typ='TXM',
1898 # ------------------------------------
1900 fr = 'Noms des points remarquables pour les impressions',
1901 ang= 'Names of remarkable points for printouts',
1905 ) # FIN OUTPUT_FILES
1908 # -----------------------------------------------------------------------
1909 CONSTRUCTION_WORKS_MODELLING = PROC(nom = "CONSTRUCTION_WORKS_MODELLING",op = None,
1910 # -----------------------------------------------------------------------
1912 # Attention calculer le logique BREACH
1914 # ------------------------------------
1915 Number_Of_Culverts = SIMP( statut = 'o',typ = 'I',
1916 # ------------------------------------
1918 fr = 'Nombre de siphons traites comme des termes sources ou puits. Ces siphons doivent etre decrits comme des sources \
1919 dans le fichier cas. Leurs caracteristiques sont donnees dans le fichier de donnees des siphons (voir la documentation ecrite)',
1920 ang = 'Number of culverts treated as source terms. They must be described as sources in the domain\
1921 and their features are given in the culvert data file (see written documentation)',),
1922 # ------------------------------------
1923 culvert_exists = BLOC(condition = "Number_Of_Culverts!= 0",
1924 # ------------------------------------
1925 # ------------------------------------
1926 Culvert_Data_File = SIMP( statut = 'o',typ = ('Fichier', 'All Files (*)',),
1927 # ------------------------------------
1928 fr = 'Fichier de description des siphons presents dans le modele',
1929 ang = 'Description of culvert existing in the model',),
1930 ), # fin bloc culvert_exists
1932 # ------------------------------------
1933 Number_Of_Tubes = SIMP( statut = 'o',typ = 'I',
1934 # ------------------------------------
1936 fr = 'Nombre de buses ou ponts traites comme des termes sources ou puits. Ces buses doivent etre decrits comme des sources\n\
1937 dans le fichier cas. Leurs caracteristiques sont donnees dans le fichier de donnees des buses (voir la documentation ecrite)',
1938 ang = 'Number of tubes or bridges treated as source terms. They must be described as sources in the domain \n\
1939 and their features are given in the tubes data file (see written documentation)',),
1940 # ------------------------------------
1941 b_Tubes = BLOC(condition = "Number_Of_Tubes!= 0",
1942 # ------------------------------------
1943 # ------------------------------------
1944 Tubes_Data_File = SIMP( statut = 'o',
1945 # ------------------------------------
1946 typ = ('Fichier', 'All Files (*)',),
1947 fr = 'Fichier de description des buses/ponts presents dans le modele',
1948 ang = 'Description of tubes/bridges existing in the model',),
1949 ), # in bloc b_Tubes
1951 # ------------------------------------
1952 Number_Of_Weirs = SIMP(statut = 'o',typ = 'I',defaut = 0,
1953 # ------------------------------------
1954 fr = 'Nombre de seuils qui seront traites par des conditions aux limites. \n\
1955 Ces seuils doivent etre decrits comme des frontieres du domaine de calcul',
1956 ang = 'Number of weirs that will be treated by boundary conditions.',
1958 # ------------------------------------
1959 b_Weirs = BLOC(condition = "Number_Of_Weirs!= 0",
1960 # ------------------------------------
1961 # ------------------------------------
1962 Weirs_Data_File = SIMP( statut = 'o',
1963 # ------------------------------------
1964 typ = ('Fichier', 'All Files (*)',),
1965 fr = 'Fichier de description des seuils presents dans le modele',
1966 ang = 'Description of weirs existing in the model',),
1968 # ------------------------------------
1969 Type_Of_Weirs = SIMP( statut = 'o',typ = 'TXM',
1970 # ------------------------------------
1971 into = ["Horizontal with same number of nodes upstream/downstream (Historical solution with bord)",
1972 "General (New solution with sources points)"],
1973 defaut = "Horizontal with same number of nodes upstream/downstream (Historical solution with bord)",
1974 fr = 'MĂ©thode de traitement des seuils ',
1975 ang = 'Method for treatment of weirs',),
1978 # ------------------------------------
1979 Breach = SIMP(statut = 'o',typ = bool,defaut = False,
1980 # ------------------------------------
1981 fr = 'Prise en compte de breches dans le calcul par modification altimetrique dans le maillage.',
1982 ang = 'Take in account some breaches during the computation by modifying the bottom level of the mesh.',),
1984 # ------------------------------------
1985 b_Breaches = BLOC (condition = 'Breach == True',
1986 # ------------------------------------
1987 # ------------------------------------
1988 Breaches_Data_File = SIMP( statut = 'o',typ = ('Fichier', 'All Files (*)',),
1989 # ------------------------------------
1990 fr = 'Fichier de description des breches',
1991 ang = 'Description of breaches',),
1995 ) # Fin CONSTRUCTION_WORKS_MODELLING
1998 # -----------------------------------------------------------------------
1999 GENERAL_PARAMETERS = PROC(nom = "GENERAL_PARAMETERS",op = None,
2000 # -----------------------------------------------------------------------
2001 UIinfo = { "groupes" : ( "CACHE", )},
2002 # ------------------------------------
2003 Location = FACT(statut = 'o',
2004 # ------------------------------------
2005 # ------------------------------------
2006 Origin_Coordinates = SIMP( statut='o',
2007 # ------------------------------------
2008 typ = Tuple(2),validators = VerifTypeTuple(('I','I')),defaut = (0,0),
2009 fr = 'Valeur en metres, utilise pour eviter les trop grands nombres, transmis dans le format Selafin mais pas d autre traitement pour l instant',
2010 ang= 'Value in metres, used to avoid large real numbers, added in Selafin format, but so far no other treatment',),
2013 # ------------------------------------
2014 Spherical_Coordinates = SIMP(typ = bool,statut = 'o',defaut = False,
2015 # ------------------------------------
2016 fr = 'Choix des coordonnees spheriques pour la realisation du calcul ( pour les grands domaines de calcul).',
2017 ang = 'Selection of spherical coordinates to perform the computation (for large computation domains).'),
2019 # ------------------------------------
2020 b_Spher = BLOC(condition = 'Spherical_Coordinates == True',
2021 # ------------------------------------
2022 # ------------------------------------
2023 Latitude_Of_Origin_Point = SIMP(typ = 'R',statut = 'o',defaut = 48.,
2024 # ------------------------------------
2025 fr = 'Determine l origine utilisee pour le calcul de latitudes lorsque l on effectue un calcul en coordonnees spheriques.',
2026 ang = 'Determines the origin used for computing latitudes when a computation is made in spherical coordinates.this latitude\n\
2027 is in particular used to compute the Coriolis force. In cartesian coordinates, Coriolis coefficient is considered constant.'),
2029 # ------------------------------------
2030 Spatial_Projection_Type = SIMP(statut = 'o',typ = 'TXM',
2031 # ------------------------------------
2032 into = ["Mercator","Latitude longitude"]),
2035 # ------------------------------------
2036 b_Spher_faux = BLOC(condition = 'Spherical_Coordinates == False',
2037 # ------------------------------------
2038 # ------------------------------------
2039 Spatial_Projection_Type = SIMP(statut = 'o',typ = 'TXM',
2040 # ------------------------------------
2041 into = ["Cartesian, not georeferenced","Mercator","Latitude longitude"],
2042 defaut = "Cartesian, not georeferenced",),
2043 ), # fin b_Spher_faux
2045 ), # Fin de Location
2046 # ------------------------------------
2047 Time = FACT(statut = 'o',
2048 # ------------------------------------
2049 regles = (AU_MOINS_UN('Number_Of_Time_Steps','Duration'),
2050 EXCLUS('Number_Of_Time_Steps','Duration'),
2053 # -----------------------------------------------------------------------
2054 Consigne = SIMP(statut = "o",homo = 'information',typ = "TXM",
2055 # -----------------------------------------------------------------------
2056 defaut = "Choose between Keywords 'Number_Of_Time_Steps' or 'Duration'"),
2058 # ------------------------------------
2059 Time_Step = SIMP(statut = 'o',
2060 # ------------------------------------
2061 typ = 'R', defaut = 1,
2062 fr = 'Definit le nombre de pas de temps effectues lors de l''execution du code.',
2063 ang = 'Specifies the number of time steps performed when running the code.'),
2065 # ------------------------------------
2066 Number_Of_Time_Steps = SIMP(statut = 'f',typ = 'I',
2067 # ------------------------------------
2068 fr = 'Definit le nombre de pas de temps effectues lors de l''execution du code.',
2069 ang = 'Specifies the number of time steps performed when running the code.'),
2071 # ------------------------------------
2072 Duration = SIMP(statut = 'f',typ = 'R',
2073 # ------------------------------------
2074 fr = 'duree de la simulation. alternative au parametre nombre de pas de temps. \n\
2075 On en deduit le nombre de pas de temps en prenant l''entier le plus proche de (duree du calcul/pas de temps).\n\
2076 Si le nombre de pas de temps est aussi donne, on prend la plus grande valeur',
2077 ang = 'duration of simulation. May be used instead of the parameter NUMBER OF TIME STEPS. \n\
2078 The nearest integer to (duration/time step) is taken. If NUMBER OF TIME STEPS is also given, the greater value is taken',),
2081 # Attention, on laisse la règle mais il est possible d avoir les 2 en entrées --> attention au convert
2082 # ------------------------------------
2083 Variable_Time_Step = SIMP(statut = 'o',typ = bool, defaut=False,
2084 # ------------------------------------
2085 fr = 'Pas de temps variable pour avoir un nombre de courant souhaite',
2086 ang = 'Variable time-step to get a given Courant number'),
2088 # ------------------------------------
2089 b_var_time = BLOC(condition = "Variable_Time_Step == True" ,
2090 # ------------------------------------
2091 # ------------------------------------
2092 Desired_Courant_Number = SIMP(statut = 'o',typ = 'R',
2093 # ------------------------------------
2094 fr = 'Nombre de Courant souhaite ',
2095 ang = 'Desired Courant number',),
2098 # ------------------------------------
2099 Original_Date_Of_Time = FACT( statut = 'o',
2100 # ------------------------------------
2101 fr = "Permet de fixer la date d'origine des temps du modele lors de la prise en compte de la force generatrice de la maree.",
2102 ang = 'Give the date of the time origin of the model when taking into account the tide generating force.',
2103 Year = SIMP(statut = 'o',typ = 'I',val_min = 1900, defaut = 1900),
2104 Month = SIMP(statut = 'o',typ = 'I',val_min = 1,val_max = 12, defaut = 1),
2105 Day = SIMP(statut = 'o',typ = 'I',val_min = 1,val_max = 31,defaut = 1),),
2107 # ------------------------------------
2108 Original_Hour_Of_Time = FACT( statut = 'o',
2109 # ------------------------------------
2110 fr = "Permet de fixer l'heure d'origine des temps du modele lors de la prise en compte de la force generatrice de la maree.",
2111 ang = 'Give the time of the time origin of the model when taking into account the tide generating force.',
2112 Hour = SIMP(statut = 'o',typ = 'I',val_min = 0,val_max = 24, defaut = 0),
2113 Minute = SIMP(statut = 'o',typ = 'I',val_min = 0,val_max = 60, defaut = 0),
2114 Second = SIMP(statut = 'o',typ = 'I',val_min = 0,val_max = 60, defaut = 0),
2117 # ------------------------------------
2118 Stop_If_A_Steady_State_Is_Reached = SIMP(statut = 'o',
2119 # ------------------------------------
2120 typ = bool,defaut = False),
2122 # ------------------------------------
2123 b_stop = BLOC(condition = "Stop_If_A_Steady_State_Is_Reached == True" ,
2124 # ------------------------------------
2125 # ------------------------------------
2126 Stop_Criteria = SIMP(statut = 'o',typ = Tuple(3),validators = VerifTypeTuple(('R','R','R')),
2127 # ------------------------------------
2128 fr = "Criteres d'arret pour un ecoulement permanent. ces coefficients sont respectivement appliques a\n\
2129 1- U et V 2- H 3- T ",
2130 ang = 'Stop criteria for a steady state These coefficients are applied respectively to\n\
2131 1- U and V 2- H 3- T ',),
2134 # ------------------------------------
2135 Control_Of_Limits = SIMP(statut = 'o',
2136 # ------------------------------------
2137 typ = bool, defaut = False,
2138 fr = 'Le programme s''arrete si les limites sur u,v,h ou t sont depassees',
2139 ang = 'The program is stopped if the limits on u,v,h, or t are trespassed',),
2141 # ------------------------------------
2142 b_limit = BLOC(condition = "Control_Of_Limit == True" ,
2143 Limit_Values = FACT(statut = 'o',
2144 # Attention : 1 seul MC ds Telemac
2145 # ------------------------------------
2146 fr = 'valeurs mini et maxi acceptables min puis max',
2147 ang = 'min and max acceptable values ',
2149 # ------------------------------------
2150 Limit_Values_H = SIMP(statut = 'o',typ = Tuple(2),
2151 # ------------------------------------
2152 validators = VerifTypeTuple(('R','R')), defaut = (-1000,9000)),
2153 # ------------------------------------
2154 Limit_Values_U = SIMP(statut = 'o',typ = Tuple(2),
2155 # ------------------------------------
2156 validators = VerifTypeTuple(('R','R')), defaut = (-1000,1000)),
2157 # ------------------------------------
2158 Limit_Values_V = SIMP(statut = 'o',typ = Tuple(2),
2159 # ------------------------------------
2160 validators = VerifTypeTuple(('R','R')), defaut = (-1000,1000)),
2161 # ------------------------------------
2162 Limit_Values_T = SIMP(statut = 'o',typ = Tuple(2),
2163 # ------------------------------------
2164 validators = VerifTypeTuple(('R','R')), defaut = (-1000,1000)),
2165 ),), # fin Fact et b_limit
2168 # Attention il faut recalculer en sortie : il faut 0 ou 1 et non un boolean
2169 # ------------------------------------
2170 Debugger = SIMP(typ = bool , statut = 'o',
2171 # ------------------------------------
2173 fr= 'Pour imprimer la sequence des appels, mettre 1',
2174 ang = 'If 1, calls of subroutines will be printed in the listing',),
2176 ) # Fin GENERAL_PARAMETERS
2179 # -----------------------------------------------------------------------
2180 TURBULENCE = PROC(nom = "TURBULENCE",op = None,
2181 # -----------------------------------------------------------------------
2183 # -----------------------------------------------------------------------
2184 Turbulence_Model = SIMP( statut = 'o',typ = 'TXM', defaut = "Constant Viscosity",
2185 # -----------------------------------------------------------------------
2186 into = ("Constant Viscosity", "Elder", "K-Epsilon Model", "Smagorinski"),
2187 fr = 'Pour Elder, il faut pas oublier d ajuster les deux valeurs du mot-cle : COEFFICIENTS ADIMENSIONNELS DE DISPERSION\n\
2188 Pour K-Epsilon Model, ce meme parametre doit retrouver sa vraie valeur physique car elle est utilisee comme telle dans le modele de turbulence',
2189 ang = 'When Elder, the two values of key-word : NON-DIMENSIONAL DISPERSION COEFFICIENTS are used \n\
2190 When K-Epsilon Model, this parameter should recover its true physical value, since it is used as such in the turbulence model.',),
2192 # ------------------------------------
2193 b_turbu_const = BLOC(condition = 'Turbulence_Model == "Constant Viscosity"',
2194 # ------------------------------------
2195 # ------------------------------------
2196 Velocity_Diffusivity = SIMP( statut = 'o',typ = 'R',
2197 # ------------------------------------
2199 fr = 'Fixe de facon uniforme pour l ensemble du domaine la valeur du coefficient de diffusion de viscosite globale (dynamique + turbulente).\n\
2200 Cette valeur peut avoir une influence non negligeable sur la forme et la taille des recirculations.',
2201 ang = 'Sets, in an even way for the whole domain, the value of the coefficient of global (dynamic+turbulent) viscosity. \n\
2202 this value may have a significant effect both on the shapes and sizes of recirculation zones.',),
2203 ), # fin b_turbu_const
2205 # ------------------------------------
2206 b_turbu_elder = BLOC(condition = 'Turbulence_Model == "Elder"',
2207 # ------------------------------------
2208 # ------------------------------------
2209 Non_Dimensional_Dispersion_Coefficients = SIMP (statut = 'o',
2210 # ------------------------------------
2211 typ = Tuple(2),validators = VerifTypeTuple(('R','R')),defaut = (6.,0.6),
2212 fr = 'coefficients longitudinal et transversal dans la formule de Elder.',
2213 ang = 'Longitudinal and transversal coefficients in elder s formula. Used only with turbulence model number 2',),
2214 ), # fin bloc b_turbu_elder
2216 # -----------------------------------------------------------------------
2217 Accuracy_Of_K = SIMP( statut = 'o',typ = 'R', defaut = 1e-09 ,
2218 # -----------------------------------------------------------------------
2219 fr = 'Fixe la precision demandee sur k pour le test d arret dans letape de diffusion et termes sources du modele k-epsilon.',
2220 ang = 'Sets the required accuracy for computing k in the diffusion and source terms step of the k-epsilon model.',),
2222 # -----------------------------------------------------------------------
2223 Accuracy_Of_Epsilon = SIMP( statut = 'o',typ = 'R', defaut = 1e-09 ,
2224 # -----------------------------------------------------------------------
2225 fr = 'Fixe la precision demandee sur epsilon pour le test darret dans letape de diffusion et termes sources de k et epsilon.',
2226 ang = 'Sets the required accuracy for computing epsilon in the diffusion and source-terms step of the k-epsilon model.',),
2228 # -----------------------------------------------------------------------
2229 Time_Step_Reduction_For_K_Epsilon_Model = SIMP( statut = 'f',typ = 'R', defaut = 1.0 ,
2230 # -----------------------------------------------------------------------
2231 fr = 'Coefficient reducteur du pas de temps pour le modele k-epsilon (qui est normalement identique a celui du systeme hydrodynamique).\n\
2232 Utilisation deconseillee',
2233 ang = 'Time step reduction coefficient for k-epsilon model (which is normally same the same as that of the hydrodynamic system).\n\
2234 Not recommended for use.',),
2236 # -----------------------------------------------------------------------
2237 Maximum_Number_Of_Iterations_For_K_And_Epsilon = SIMP( statut = 'o',typ = 'I',
2238 # -----------------------------------------------------------------------
2240 fr = 'Fixe le nombre maximum diterations accepte lors de la resolution du systeme diffusion-termes sources du modele k-epsilon.',
2241 ang = 'Sets the maximum number of iterations that are acceptable when solving the diffusion source-terms step of the k-epsilon model.',),
2243 # -----------------------------------------------------------------------
2244 Turbulence_Model_For_Solid_Boundaries = SIMP( statut = 'o',typ = 'TXM',
2245 # -----------------------------------------------------------------------
2247 into = ('Smooth', 'Rough'),
2248 fr = 'Permet de choisir le regime de turbulence aux parois ',
2249 ang = 'Provided for selecting the type of friction on the walls',),
2251 # -----------------------------------------------------------------------
2252 Solver_For_K_Epsilon_Model = SIMP( statut = 'o',typ = 'TXM',
2253 # -----------------------------------------------------------------------
2254 defaut = "Conjugate gradient" ,
2255 into = ("Conjugate gradient", "Conjugate residuals", "Conjugate gradient on normal equation",
2256 "Minimum error", "Conjugate gradient squared", "Conjugate gradient squared stabilised (CGSTAB)",
2258 fr = 'Permet de choisir le solveur utilise pour la resolution du systeme du modele k-epsilon',
2259 ang = 'Makes it possible to select the solver used for solving the system of the k-epsilon model.',),
2261 # -----------------------------------------------------------------------
2262 b_gmres = BLOC(condition = 'Solver_For_K_Epsilon_Model == "GMRES"',
2263 # -----------------------------------------------------------------------
2264 # -----------------------------------------------------------------------
2265 Option_For_The_Solver_For_K_Epsilon_Model = SIMP( statut = 'o',typ = 'I',
2266 # -----------------------------------------------------------------------
2267 defaut = 2 ,val_min = 2,val_max = 15,
2268 fr = 'le mot cle est la dimension de lespace de KRILOV (valeurs conseillees entre 2 et 7)',
2269 ang = 'dimension of the krylov space try values between 2 and 7',),
2270 ), # fin bloc b_gmres
2272 # -----------------------------------------------------------------------
2273 Preconditioning_For_K_Epsilon_Model = SIMP( statut = 'o',typ = 'TXM',
2274 # -----------------------------------------------------------------------
2275 defaut = 'Diagonal' ,
2276 into = ("Diagonal", "No preconditioning", "Diagonal condensed", "Crout", "Diagonal and crout", "Diagonal condensed and crout"),
2277 fr = 'Permet de preconditionner le systeme relatif au modele k-epsilon',
2278 ang = 'Preconditioning of the linear system in the diffusion step of the k-epsilon model.',
2280 # -----------------------------------------------------------------------
2281 Information_About_K_Epsilon_Model = SIMP(statut = 'o',typ = bool,defaut = True,
2282 # -----------------------------------------------------------------------
2283 fr = 'Donne le nombre d iterations du solveur de l etape de diffusion et termes sources du modele k-epsilon.',
2284 ang = 'Gives the number of iterations of the solver in the diffusion and source terms step of the k-epsilon model.',
2291 # -----------------------------------------------------------------------
2292 PARTICLE_TRANSPORT = PROC(nom = "PARTICLE_TRANSPORT",op = None,
2293 # -----------------------------------------------------------------------
2294 # -----------------------------------------------------------------------
2295 Number_Of_Drogues = SIMP(statut = 'o',typ = 'I',defaut = 0,
2296 # -----------------------------------------------------------------------
2297 fr = 'Permet d''effectuer un suivi de flotteurs',
2298 ang = 'Number of drogues in the computation.',),
2300 # -----------------------------------------------------------------------
2301 Algae_Transport_Model = SIMP( statut = 'o',typ = bool, defaut = False ,
2302 # -----------------------------------------------------------------------
2303 fr = 'Si oui, les flotteurs seront des algues',
2304 ang = 'If yes, the floats or particles will be algae',),
2306 # -----------------------------------------------------------------------
2307 algae_exists = BLOC(condition = "Algae_Transport_Model == True",
2308 # -----------------------------------------------------------------------
2309 # -----------------------------------------------------------------------
2310 Algae_Type = SIMP( statut = 'o',typ = 'TXM',
2311 # -----------------------------------------------------------------------
2312 into = ["Sphere", "Iridaea flaccida (close to ulva)", "Pelvetiopsis limitata", "Gigartina leptorhynchos"],
2314 fr = 'Type des algues. Pour sphere les algues seront modelisees comme des spheres, pour les autres choix voir Gaylord et al.(1994)',
2315 ang = 'Algae type. For sphere, the algae particles will be modeled as spheres, for the other choices see Gaylord et al.(1994)',),
2317 # -----------------------------------------------------------------------
2318 Diameter_Of_Algae = SIMP( statut = 'o',typ = 'R', defaut = 0.1 ,
2319 # -----------------------------------------------------------------------
2320 fr = 'Diametre des algues en m',
2321 ang = 'Diametre of algae in m',),
2323 # -----------------------------------------------------------------------
2324 Density_Of_Algae = SIMP( statut = 'o',typ = 'R', defaut = 1050.0 ,
2325 # -----------------------------------------------------------------------
2326 fr = 'Masse volumique des algues en kg/m3',
2327 ang = 'Density of algae in kg/m3',),
2329 # -----------------------------------------------------------------------
2330 Thickness_Of_Algae = SIMP( statut = 'o',typ = 'R', defaut = 0.01 ,
2331 # -----------------------------------------------------------------------
2332 fr = 'Epaisseur des algues en m',
2333 ang = 'Thickness of algae in m',),
2337 # -----------------------------------------------------------------------
2338 Oil_Spill_Model = SIMP( statut = 'o',typ = bool, defaut = False ,
2339 # -----------------------------------------------------------------------
2340 fr = 'pour declencher le modele de derive de nappes, dans ce cas le fichier de commandes migrhycar est necessaire',
2341 ang = 'will trigger the oil spill model, in this case the migrhycar steering file is needed',),
2343 # -----------------------------------------------------------------------
2344 oil_exists = BLOC(condition = "Oil_Spill_Model == True",
2345 # -----------------------------------------------------------------------
2346 # -----------------------------------------------------------------------
2347 Oil_Spill_Steering_File = SIMP( statut = 'o',typ = ('Fichier', 'All Files (*)',),
2348 # -----------------------------------------------------------------------
2349 fr = 'Contient les donnees pour le modele de derive de nappes',
2350 ang = 'Contains data for the oil spill model',),
2353 # -----------------------------------------------------------------------
2354 drogues_exists = BLOC(condition = "Number_Of_Drogues!= 0 or Algae_Transport_Model == True or Oil_Spill_Model == True",
2355 # -----------------------------------------------------------------------
2356 # -----------------------------------------------------------------------
2357 Drogues_File = SIMP( statut = 'o',typ = ('Fichier', 'All Files (*)',),
2358 # -----------------------------------------------------------------------
2359 fr = 'Fichier de resultat avec les positions des flotteurs',
2360 ang = 'Results file with positions of drogues',),
2362 # -----------------------------------------------------------------------
2363 Printout_Period_For_Drogues = SIMP(statut = 'o',typ = 'I',defaut = 1,
2364 # -----------------------------------------------------------------------
2365 fr = 'Nombre de pas de temps entre 2 sorties de positions de flotteurs dans le fichier des resultats binaire supplementaire\n\
2366 N affecte pas la qualite du calcul de la trajectoire',
2367 ang = 'Number of time steps between 2 outputs of drogues positions in the binary file',),
2368 ),#fin drogues ou algae
2371 # -----------------------------------------------------------------------
2372 Stochastic_Diffusion_Model = SIMP( statut = 'o',typ = 'I', defaut = 0 ,
2373 # -----------------------------------------------------------------------
2374 fr = 'Pour les particules : flotteurs, algues, hydrocarbures',
2375 ang = 'Meant for particles: drogues, algae, oil spills',),
2377 # -----------------------------------------------------------------------
2378 Number_Of_Lagrangian_Drifts = SIMP( statut = 'o',typ = 'I', defaut = 0 ,
2379 # -----------------------------------------------------------------------
2380 fr = 'Permet deffectuer simultanement plusieurs calculs de derives lagrangiennes initiees a des pas differents',
2381 ang = 'Provided for performing several computations of lagrangian drifts starting at different times.',),
2383 # -----------------------------------------------------------------------
2384 b_cons = BLOC(condition = "Number_Of_Lagrangian_Drifts != 0",
2385 # -----------------------------------------------------------------------
2386 # -----------------------------------------------------------------------
2387 Consigne = SIMP(statut = "o",homo = 'information',typ = "TXM",
2388 # -----------------------------------------------------------------------
2389 defaut = "Add A and G in the VARIABLES FOR GRAPHIC PRINTOUTS key-word in POST_PROCESSING SECTION"),
2393 # -----------------------------------------------------------------------
2394 TRACERS = PROC(nom = "TRACERS",op = None,
2395 # -----------------------------------------------------------------------
2397 # -----------------------------------------------------------------------
2398 Tracers_Setting = FACT(statut = 'o',
2399 # -----------------------------------------------------------------------
2401 # -----------------------------------------------------------------------
2402 Number_Of_Tracers = SIMP( statut='o',typ='I',
2403 # -----------------------------------------------------------------------
2405 fr = 'Definit le nombre de traceurs.',
2406 ang= 'Defines the number of tracers',),
2407 #PNPNPN Recalculer Names_Of_Tracers et Initial_Values_Of_Tracers comme des listes
2408 # pour Names_Of_Tracers = Names_Of_Tracers+Names_Of_Unit
2409 # il faut faire un validateur (la chaine doit faire 16 caracteres evtuellement complete par des blancs)
2411 # ------------------------------------
2412 Tracer = FACT(statut = 'o', max="**",
2413 # ------------------------------------
2414 # -----------------------------------------------------------------------
2415 Name_Of_Tracer = SIMP( statut='o',typ='TXM',
2416 # -----------------------------------------------------------------------
2417 fr = 'Noms des traceurs en 16 caracteres',
2418 ang= 'Name of tracers in 32 characters',),
2420 # -----------------------------------------------------------------------
2421 Name_Of_Unit = SIMP( statut='o',typ='TXM',
2422 # -----------------------------------------------------------------------
2423 fr = 'Noms de l unité en 16 caracteres',
2424 ang= 'Name of unit in 16 characters',),
2426 b_Computation_Continued = BLOC(condition = 'Computation_Continued == True',
2427 #PNPNPN Attention: global_jdc ne fonctionne pas bien : pas de propagation si chgt de valeur de Computation_Continued
2428 # -----------------------------------------------------------------------
2429 Initial_Values_Of_Tracers = SIMP( statut='o',
2430 # -----------------------------------------------------------------------
2431 typ = Tuple(2),validators = VerifTypeTuple(('R','R')),
2433 fr = 'Fixe la valeur initiale du traceur.',
2434 ang= 'Sets the initial value of the tracer.',),
2436 ), # fin b_Computation_Continued
2437 # ------------------------------------
2438 Boundary_Conditions = FACT( statut = 'f',
2439 # ------------------------------------
2440 # -----------------------------------------------------------------------
2441 Prescribed_Tracers_Values = SIMP( statut='o',
2442 # -----------------------------------------------------------------------
2443 typ = Tuple(2),validators = VerifTypeTuple(('R','R')),
2444 fr = 'Valeurs du traceur imposees aux frontieres liquides entrantes. Lire la partie du manuel consacree aux conditions aux limites',
2445 ang= 'Tracer values prescribed at the inflow boundaries. Read the manual section dealing with the boundary conditions',),
2446 ), # fin Boundary_Conditions
2449 # -----------------------------------------------------------------------
2450 Density_Effects = SIMP( statut='o',typ=bool,
2451 # -----------------------------------------------------------------------
2453 fr = 'prise en compte du gradient horizontal de densite le traceur est alors la salinite',
2454 ang= 'the horizontal gradient of density is taken into account the tracer is then the salinity',),
2456 # -----------------------------------------------------------------------
2457 b_Density_Effects = BLOC(condition = 'Density_Effects == True',
2458 # -----------------------------------------------------------------------
2459 # ------------------------------------
2460 Consigne = SIMP(statut = "o",homo = 'information',typ = "TXM",
2461 # ------------------------------------
2462 defaut='the first Tracer must be the salinity expressed in kg/m3'),
2464 # -----------------------------------------------------------------------
2465 Mean_Temperature = SIMP( statut='o',typ='R',
2466 # -----------------------------------------------------------------------
2468 fr = 'temperature de reference pour le calcul des effets de densite ',
2469 ang= 'reference temperature for density effects',),
2471 ), # fin b_Density_Effects
2473 ), # fin b_Tracers_Settings
2474 # -----------------------------------------------------------------------
2475 Solving = FACT( statut='o',
2476 # -----------------------------------------------------------------------
2477 # -----------------------------------------------------------------------
2478 Solver_For_Diffusion_Of_Tracers = SIMP( statut='o',typ='TXM',
2479 # -----------------------------------------------------------------------
2480 defaut='1="conjugate gradient"' ,
2481 into =('1="conjugate gradient"', '2="conjugate residual"', '3="conjugate gradient on a normal equation"',
2482 '4="minimum error"', '5="squared conjugate gradient"', '6="cgstab"', '7="gmres "', '8="direct"'),),
2484 # -----------------------------------------------------------------------
2485 Solver_Option_For_Tracers_Diffusion = SIMP( statut='o',typ='I',
2486 # -----------------------------------------------------------------------
2488 fr = 'si le solveur est GMRES (7) le mot cle est la dimension de lespace de KRILOV (valeurs conseillees entre 2 et 15)',
2489 ang= 'WHEN GMRES (7) IS CHOSEN, DIMENSION OF THE KRYLOV SPACE TRY VALUES BETWEEN 2 AND 15',),
2491 # -----------------------------------------------------------------------
2492 Preconditioning_For_Diffusion_Of_Tracers = SIMP( statut='o',typ='TXM',
2493 # -----------------------------------------------------------------------
2494 defaut='2="diagonal"' ,
2495 into =('2="diagonal"', '0="no preconditioning "', '3="diagonal condensed"', '7="crout"', '14="diagonal and crout"', '21="diagonal condensed and crout"'),
2496 fr = 'Permet de preconditionner le systeme relatif au traceur. Memes definition et possibilites que pour le mot-cle PRECONDITIONNEMENT.',
2497 ang= 'Preconditioning of the linear system in the tracer diffusion step. Same definition and possibilities as for the keyword PRECONDITIONING',
2501 # -----------------------------------------------------------------------
2502 Accuracy = FACT( statut='o',
2503 # -----------------------------------------------------------------------
2504 # -----------------------------------------------------------------------
2505 Accuracy_For_Diffusion_Of_Tracers = SIMP( statut='o',typ='R', defaut=1e-06 ,
2506 # -----------------------------------------------------------------------
2507 fr = 'Fixe la precision demandee pour le calcul de la diffusion du traceur.',
2508 ang= 'Sets the required accuracy for computing the tracer diffusion.',),
2510 # -----------------------------------------------------------------------
2511 Maximum_Number_Of_Iterations_For_Diffusion_Of_Tracers = SIMP( statut='o',typ='I', defaut=60 ,
2512 # -----------------------------------------------------------------------
2513 fr = 'Limite le nombre diterations du solveur a chaque pas de temps pour le calcul de la diffusion du traceur.',
2514 ang= 'Limits the number of solver iterations at each time step for the diffusion of tracer.',),
2517 # -----------------------------------------------------------------------
2518 Sources = FACT( statut='o',
2519 # -----------------------------------------------------------------------
2520 # ------------------------------------
2521 Consigne = SIMP(statut = "o",homo = 'information',typ = "TXM",
2522 # ------------------------------------
2523 defaut = "La longueur de la liste doit etre nb de source * nb de tracers"),
2524 # -----------------------------------------------------------------------
2525 Values_Of_The_Tracers_At_The_Sources = SIMP( statut='o',typ='R', max='**' ,
2526 # -----------------------------------------------------------------------
2527 fr = 'Valeurs des traceurs a chacune des sources',
2528 ang= 'Values of the tracers at the sources',),
2530 # -----------------------------------------------------------------------
2531 Metereology = FACT( statut='o',
2532 # -----------------------------------------------------------------------
2533 # en fait, c'est une liste de Tuple de 2. Il faudrait caluler la taille en fonction du Nombre de sources
2534 # -----------------------------------------------------------------------
2535 Values_Of_Tracers_In_The_Rain = SIMP(
2536 # -----------------------------------------------------------------------
2537 statut='o',typ='R',defaut=0, max=2 , fr = '', ang= '',),
2538 ), # fin Metereology
2540 # -----------------------------------------------------------------------
2541 Numerical = FACT( statut='o',
2542 # -----------------------------------------------------------------------
2544 # -----------------------------------------------------------------------
2545 Implicitation_Coefficient_Of_Tracers = SIMP( statut='o',typ='R',
2546 # -----------------------------------------------------------------------
2548 fr = 'Fixe la valeur du coefficient dimplicitation du traceur',
2549 ang= 'Sets the value of the implicitation coefficient for the tracer',),
2551 # -----------------------------------------------------------------------
2552 Diffusion_Of_Tracers = SIMP( statut='o',typ=bool,
2553 # -----------------------------------------------------------------------
2555 fr = 'Prise en compte ou non de la diffusion du traceur passif.',
2556 ang= 'The diffusion of the passive tracer is taken into account or ignored.',),
2558 # ------------------------------------
2559 b_Diffusion_Of_Tracers = BLOC(condition = 'Diffusion_Of_Tracers == True',
2560 # ------------------------------------
2561 # ------------------------------------
2562 Coefficient_For_Diffusion_Of_Tracers = SIMP( statut='o',typ='R',
2563 # ------------------------------------
2565 fr = 'Fixe la valeur du coefficient de diffusion du traceur. Linfluence de ce parametre sur levolution du traceur dans le temps est importante.',
2566 ang= 'Sets the value of the tracer diffusivity.',),
2568 # ------------------------------------
2569 Option_For_The_Diffusion_Of_Tracers = SIMP( statut='o',typ='TXM',
2570 # ------------------------------------
2571 defaut='Diffusion in the form div( nu grad(T))' ,
2572 into=[ 'Diffusion in the form div( nu grad(T))', 'Diffusion in the form 1/h div ( h nu grad(T))',],),
2573 ), # fin b_Diffusion_Of_Tracers
2575 # ------------------------------------
2576 Scheme_For_Advection_Of_Tracers = SIMP( statut='o',typ='TXM',
2577 # ------------------------------------
2578 defaut="CHARACTERISTICS" ,
2579 into =("NO ADVECTION", "CHARACTERISTICS", "EXPLICIT + SUPG", "EXPLICIT LEO POSTMA", "EXPLICIT + MURD SCHEME N",
2580 "EXPLICIT + MURD SCHEME PSI", "LEO POSTMA FOR TIDAL FLATS", "N-SCHEME FOR TIDAL FLATS"),
2581 fr = 'Choix du schema de convection pour les traceurs, remplace FORME DE LA CONVECTION',
2582 ang= 'Choice of the advection scheme for the tracers, replaces TYPE OF ADVECTION',),
2584 # ------------------------------------
2585 Scheme_Option_For_Advection_Of_Tracers = SIMP( statut='o',typ='TXM',
2586 # ------------------------------------
2588 into=['explicit','predictor-corrector for tracers'],
2589 fr = 'Si present remplace et a priorite sur : OPTION POUR LES CARACTERISTIQUES OPTION DE SUPG Si schema PSI : 1=explicite 2=predicteur-correcteur pour les traceurs',
2590 ang= 'If present replaces and has priority over: OPTION FOR CHARACTERISTICS SUPG OPTION IF PSI SCHEME: 1=explicit 2=predictor-corrector for tracers',),
2592 # ------------------------------------
2593 Mass_Lumping_On_Tracers = SIMP ( statut='o',typ='R',
2594 # ------------------------------------
2596 fr = 'Fixe le taux de mass-lumping effectue sur le traceur.',
2597 ang = 'Sets the amount of mass-lumping that is performed on the tracer.',),
2600 # -----------------------------------------------------------------------
2601 Degradation = FACT( statut='o',
2602 # -----------------------------------------------------------------------
2604 # PN Attention, il faut recalculer Law_Of_Tracers_Degradation
2605 # et les coefficients.
2606 # Question : pourquoi 2 et pas selon le nb de tracer
2607 # Est ce que ce $ va sous tracer ?
2608 # -----------------------------------------------------------------------
2609 Law1_Of_Tracers_Degradation = SIMP( statut='o',typ='TXM',
2610 # -----------------------------------------------------------------------
2611 into=["NO DEGRADATION","F(T90) LAW"],
2612 defaut="NO DEGRADATION",
2613 fr = 'Prise en compte dune loi de decroissance des traceurs',
2614 ang= 'Take in account a law for tracers decrease',),
2616 # -----------------------------------------------------------------------
2617 b_Law1 = BLOC(condition = 'Law1_Of_Tracers_Degradation == "F(T90) LAW"',
2618 # -----------------------------------------------------------------------
2619 # -----------------------------------------------------------------------
2620 Coefficient_1_For_Law_Of_Tracers_Degradation = SIMP( statut='o',typ='R',
2621 # -----------------------------------------------------------------------
2622 fr = 'Coefficient 1 de la loi de decroissance des traceurs',
2623 ang= 'Coefficient 1 of law for tracers decrease',),
2626 # -----------------------------------------------------------------------
2627 Law2_Of_Tracers_Degradation = SIMP( statut='o',typ='TXM',
2628 # -----------------------------------------------------------------------
2629 into=["NO DEGRADATION","F(T90) LAW"],
2630 defaut="NO DEGRADATION",
2631 fr = 'Prise en compte dune loi de decroissance des traceurs',
2632 ang= 'Take in account a law for tracers decrease',),
2634 # -----------------------------------------------------------------------
2635 b_Law2 = BLOC(condition = 'Law2_Of_Tracers_Degradation == "F(T90) LAW"',
2636 # -----------------------------------------------------------------------
2637 # -----------------------------------------------------------------------
2638 Coefficient_2_For_Law_Of_Tracers_Degradation = SIMP( statut='o',typ='R',
2639 # -----------------------------------------------------------------------
2640 fr = 'Coefficient 2 de la loi de decroissance des traceurs',
2641 ang= 'Coefficient 2 of law for tracers decrease',),
2643 ), # fin Degradation
2648 Ordre_Des_Commandes = ( 'INITIALIZATION', 'BOUNDARY_CONDITIONS','GENERAL_PARAMETERS', 'PHYSICAL_PARAMETERS', 'NUMERICAL_PARAMETERS',
2649 'TURBULENCE', 'TRACERS', 'PARTICLE_TRANSPORT', 'CONSTRUCTION_WORKS_MODELLING', 'TIDE_PARAMETERS', 'OUTPUT_FILES')