9 def __convert__(self,valeur):
10 if type(valeur) == types.StringType: return None
11 if len(valeur) != self.ntuple: return None
15 return "Date : jj/mm/aaaa "
25 def __init__(self,ntuple):
28 def __convert__(self,valeur):
29 if type(valeur) == types.StringType:
31 if len(valeur) != self.ntuple:
36 return "Tuple de %s elements" % self.ntuple
40 JdC = JDC_CATA (code = 'TELEMAC',
43 # =======================================================================
44 # Catalog entry for the MAP function : c_pre_interfaceBody_mesh
45 # =======================================================================
47 VERSION_CATALOGUE="TRUNK"
48 # -----------------------------------------------------------------------
49 COMPUTATION_ENVIRONMENT = PROC(nom= "COMPUTATION_ENVIRONMENT",op = None,
50 # -----------------------------------------------------------------------
51 UIinfo = {"groupes": ("CACHE")},
52 # -----------------------------------
53 INITIALIZATION = FACT(statut='o',
54 # -----------------------------------
55 # -----------------------------------
56 TITLE = SIMP(statut ='o',
57 # -----------------------------------
60 fr = """Titre du cas etudie. Ce titre figurera sur les dessins.""",
61 ang = """Title of the case being considered. This title shall be marked on the
64 # -----------------------------------
65 INITIAL_CONDITIONS = SIMP(statut ='o',
66 # -----------------------------------
68 into = ['ZERO ELEVATION','CONSTANT ELEVATION','ZERO DEPTH','CONSTANT DEPTH','SPECIAL','PARTICULIERES','PARTICULAR','TPXO SATELLITE ALTIMETRY'],
69 defaut = 'ZERO ELEVATION',
70 fr = """ Permet de definir les conditions initiales sur les hauteurs d''eau.
71 Les valeurs possibles sont :
73 Initialise la cote de surface libre a 0. Les hauteurs d''eau initiales
74 sont alors retrouvees en faisant la difference entre les cotes de
75 surface libre et du fond.
77 Initialise la cote de surface libre a la valeur donnee par le mot-cle
78 COTE INITIALE. Les hauteurs d''eau initiales sont calculees comme
81 Initialise les hauteurs d''eau a 0.
83 Initialise les hauteurs d''eau a la valeur donnee par le mot-cle HAUTEUR
86 Les conditions initiales sur la hauteur d''eau doivent etre precisees
87 dans le sous-programme CONDIN.
88 - ALTIMETRIE SATELLITE TPXO. Les conditions initiales sur la hauteur
89 d''eau et les vitesses sont etiblies sur la base des donnees satellite
90 TPXO dont les 8 premiers constistuents ont ete extrait et sauves dans le
91 fichier BASE DE DONNEES DE MAREE.""",
92 ang = """ Makes it possible to define the initial conditions with the water
93 depth. The possible values are as follows:
95 Initializes the free surface elevation to 0. The initial water depths
96 are then found by computing the difference between the free surface and
98 - CONSTANT ELEVATION-.
99 Initializes the water elevation to
100 the value given by the keyword -INITIAL ELEVATION-. The initial water
101 depths are computed as in the previous case.
104 the water depths to 0.
105 - CONSTANT DEPTH-. Initializes the water depths
106 to the value given by the key-word -INITIAL DEPTH-.
108 The initial conditions with the water depth should be stated in the
110 - TPXO SATELITE ALTIMETRY.
111 The initial conditions on the free surface and velocities are
112 established from the TPXO satellite program data, the harmonic
113 constituents of which are stored in the TIDE DATA BASE file.""",
115 # -----------------------------------
116 b_INITIAL_CONDITIONSG = BLOC(condition="INITIAL_CONDITIONS == 'CONSTANT ELEVATION'",
117 # -----------------------------------
118 # -----------------------------------
119 INITIAL_ELEVATION = SIMP(statut ='o',
120 # -----------------------------------
123 fr = """ Valeur utilisee avec l''option : CONDITIONS INITIALES - COTE
125 ang = """ Value to be used with the option : INITIAL CONDITIONS -CONSTANT
129 # -----------------------------------
130 b_INITIAL_CONDITIONSH = BLOC(condition="INITIAL_CONDITIONS == 'CONSTANT DEPTH'",
131 # -----------------------------------
132 # -----------------------------------
133 INITIAL_DEPTH = SIMP(statut ='o',
134 # -----------------------------------
137 fr = """ Valeur utilisee avec l''option : CONDITIONS INITIALES :-HAUTEUR
139 ang = """ Value to be used along with the option: INITIAL CONDITIONS -CONSTANT
143 # -----------------------------------
144 b_INITIAL_CONDITIONSI = BLOC(condition="INITIAL_CONDITIONS == 'TPXO SATELLITE ALTIMETRY'",
145 # -----------------------------------
146 # -----------------------------------
147 ASCII_DATABASE_FOR_TIDE = SIMP(statut ='o',
148 # -----------------------------------
149 typ = ('Fichier','All Files (*)'),
151 fr = """ Base de donnees de constantes harmoniques tirees du fichier du modele
152 de maree. Ancien nom en version 6.1 : BASE DE DONNEES DE MAREE""",
153 ang = """ Tide data base of harmonic constituents extracted from the tidal model
154 file. Old name in 6.1 version: TIDE DATA BASE""",
157 # -----------------------------------
158 b_INITIAL_CONDITIONSJ = BLOC(condition="INITIAL_CONDITIONS == 'SPECIAL'",
159 # -----------------------------------
160 # -----------------------------------
161 Consigne = SIMP(statut ="o", homo="information", typ="TXM",
162 # -----------------------------------
163 defaut = "The initial conditions with the water depth should be stated in the CONDIN subroutine."),
165 # -----------------------------------
166 BINARY_DATA_FILE_1_FORMAT = SIMP(statut ='f',
167 # -----------------------------------
169 into = ['BIN','SERAFIN','SERAFIND','MED'],
171 fr = """ Format du fichier de donnes binaire. Les valeurs possibles sont : -
172 BIN : format binaire standard - SERAFIN : format standard simple
173 precision pour Telemac; - SERAFIND: format standard double precision
174 pour Telemac; - MED : format MED base sur HDF5""",
175 ang = """ Binary data file 1 format. Possible values are: - BIN : Standard
176 binary format - SERAFIN : classical single precision format in Telemac;
177 - SERAFIND: classical double precision format in Telemac; - MED : MED
178 format based on HDF5""",
180 # -----------------------------------
181 BINARY_DATA_FILE_1 = SIMP(statut ='f',
182 # -----------------------------------
183 typ = ('Fichier','All Files (*)'),
185 fr = """ Fichier de donnees code en binaire mis a la disposition de
186 l''utilisateur. Les donnees de ce fichier seront a lire sur le canal
188 ang = """ Binary-coded data file made available to the user. The data in this
189 file shall be read on channel 24.""",
191 # -----------------------------------
192 BINARY_DATA_FILE_2_FORMAT = SIMP(statut ='f',
193 # -----------------------------------
195 into = ['BIN','SERAFIN','SERAFIND','MED'],
197 fr = """ Format du fichier de donnees binaire 2. Les valeurs possibles sont : -
198 BIN : format binaire standard - SERAFIN : format standard simple
199 precision pour Telemac; - SERAFIND: format standard double precision
200 pour Telemac; - MED : format MED base sur HDF5""",
201 ang = """ Binary data file 2 format. Possible values are: - BIN : Standard
202 binary format - SERAFIN : classical single precision format in Telemac;
203 - SERAFIND: classical double precision format in Telemac; - MED : MED
204 format based on HDF5""",
206 # -----------------------------------
207 BINARY_DATA_FILE_2 = SIMP(statut ='f',
208 # -----------------------------------
209 typ = ('Fichier','All Files (*)'),
211 fr = """ Fichier de donnees code en binaire mis a la disposition de
212 l''utilisateur. Les donnees de ce fichier seront a lire sur le canal
214 ang = """ Binary-coded data file made available to the user. The data in this
215 file shall be read on channel 25.""",
217 # -----------------------------------
218 FORMATTED_DATA_FILE_1 = SIMP(statut ='f',
219 # -----------------------------------
220 typ = ('Fichier','All Files (*)'),
222 fr = """ Fichier de donnees formate mis a la disposition de l''utilisateur. Les
223 donnees de ce fichier seront a lire sur le canal 26.""",
224 ang = """ Formatted data file made available to the user. The data in this file
225 shall be read on channel 26.""",
227 # -----------------------------------
228 FORMATTED_DATA_FILE_2 = SIMP(statut ='f',
229 # -----------------------------------
230 typ = ('Fichier','All Files (*)'),
232 fr = """ Fichier de donnees formate mis a la disposition de l''utilisateur. Les
233 donnees de ce fichier seront a lire sur le canal 27.""",
234 ang = """ Formatted data file made available to the user. The data in this file
235 shall be read on channel 27.""",
237 # -----------------------------------
238 INPUT_FILES = FACT(statut='o',
239 # -----------------------------------
240 # -----------------------------------
241 GEOMETRY_FILE_FORMAT = SIMP(statut ='o',
242 # -----------------------------------
244 into = ['SERAFIN?','SERAFIND','MED'],
246 fr = """ Format du fichier de geometrie. Les valeurs possibles sont : - SERAFIN
247 : format standard simple precision pour Telemac; - SERAFIND: format
248 standard double precision pour Telemac; - MED : format MED base sur
250 ang = """ Geometry file format. Possible values are: - SERAFIN : classical
251 single precision format in Telemac; - SERAFIND: classical double
252 precision format in Telemac; - MED : MED format based on HDF5""",
254 # -----------------------------------
255 GEOMETRY_FILE = SIMP(statut ='o',
256 # -----------------------------------
257 typ = ('Fichier','All Files (*)'),
258 fr = """ Nom du fichier contenant le maillage du calcul a realiser.""",
259 ang = """ Name of the file containing the mesh. This file may also contain the
260 topography and the friction coefficients.""",
262 # -----------------------------------
263 FORTRAN_FILE = SIMP(statut ='f',
264 # -----------------------------------
265 typ = ('Fichier','All Files (*)'),
267 fr = """ Nom du fichier FORTRAN a soumettre.""",
268 ang = """ Name of FORTRAN file to be submitted.""",
270 # -----------------------------------
271 BOTTOM_TOPOGRAPHY_FILE = SIMP(statut ='f',
272 # -----------------------------------
273 typ = ('Fichier','All Files (*)'),
275 fr = """ Nom du fichier eventuel contenant la bathymetrie associee au maillage.
276 Si ce mot-cle est utilise; c''est cette bathymetrie qui sera utilisee
278 ang = """ Name of the possible file containing the bathymetric data. Where this
279 keyword is used, these bathymetric data shall be used in the
282 # -----------------------------------
283 BOTTOM_SMOOTHINGS = SIMP(statut ='o',
284 # -----------------------------------
287 fr = """ Nombre de lissages effectues sur la topographie. chaque lissage,
288 effectue a l''aide d''une matrice de masse, est conservatif. Utilise
289 lorsque les donnees de bathymetrie donnent des resultats trop
290 irreguliers apres interpolation.""",
291 ang = """ Number of smoothings on bottom topography. each smoothing is mass
292 conservative. to be used when interpolation of bathymetry on the mesh
293 gives very rough results.""",
295 # -----------------------------------
296 BOUNDARY_CONDITIONS_FILE = SIMP(statut ='o',
297 # -----------------------------------
298 typ = ('Fichier','All Files (*)'),
299 fr = """ Nom du fichier contenant les types de conditions aux limites. Ce
300 fichier est rempli de facon automatique par le mailleur au moyen de
301 couleurs affectees aux noeuds des frontieres du domaine de calcul.""",
302 ang = """ Name of the file containing the types of boundary conditions. This
303 file is filled automatically by the mesh generator through through
304 colours that are assigned to the boundary nodes.""",
306 # -----------------------------------
307 VALIDATION = SIMP(statut ='f',
308 # -----------------------------------
311 fr = """ Option utilisee principalement pour le dossier de validation. Le
312 fichier des resultats du calcul precedent est alors considere comme une
313 reference a laquelle on va comparer le calcul. La comparaison est
314 effectuee par le sous-programme VALIDA qui peut etre une comparaison
315 avec une solution exacte par exemple.""",
316 ang = """ This option is primarily used for the validation documents. The
317 PREVIOUS COMPUTATION FILE is then considered as a reference which the
318 computation is going to be compared with. The comparison is made by the
319 subroutine VALIDA, which can be modified as to so as to include, for
320 example,a comparison with an exact solution.""",
322 # -----------------------------------
323 b_VALIDATIONG = BLOC(condition="VALIDATION == True",
324 # -----------------------------------
325 # -----------------------------------
326 REFERENCE_FILE_FORMAT = SIMP(statut ='o',
327 # -----------------------------------
329 into = ['SERAFIN?','SERAFIND','MED'],
331 fr = """ Format du fichier de resultats du calcul precedent. Les valeurs
333 - SERAFIN : format standard simple precision pour Telemac;
334 - SERAFIND: format standard double precision pour Telemac;
335 - MED : format MED base sur HDF5""",
336 ang = """ Previous computation results file format. Possible values are:
337 - SERAFIN : classical single precision format in Telemac;
338 - SERAFIND: classical double precision format in Telemac;
339 - MED : MED format based on HDF5""",
341 # -----------------------------------
342 REFERENCE_FILE = SIMP(statut ='o',
343 # -----------------------------------
344 typ = ('Fichier','All Files (*)'),
346 fr = """ Fichier de resultats de reference pour la validation. Les resultats a
347 placer dans ce fichier seront a ecrire sur le canal 22.""",
348 ang = """ Binary-coded result file for validation. The results to be entered
349 into this file shall be written on channel 22.""",
353 # -----------------------------------
354 GLOBAL = FACT(statut='o',
355 # -----------------------------------
356 # -----------------------------------
357 PARALLEL_PROCESSORS = SIMP(statut ='f',
358 # -----------------------------------
361 fr = """ NOMBRE DE PROCESSEURS EN CALCUL PARALLELE 0 : 1 machine, compilation
362 sans bibliotheque de parallelisme 1 : 1 machine, compilation avec
363 bibliotheque de parallelisme 2 : 2 processeurs ou machines en parallele
365 ang = """ NUMBER OF PROCESSORS FOR PARALLEL PROCESSING 0 : 1 machine, compiling
366 without parallel library 1 : 1 machine, compiling with a parallel
367 library 2 : 2 processors or machines in parallel etc....""",
369 # -----------------------------------
370 CHECKING_THE_MESH = SIMP(statut ='o',
371 # -----------------------------------
374 fr = """ Si oui on appelle le sous-programme checkmesh qui verifie la coherence
375 du maillage, points superposes, etc.""",
376 ang = """ if this key word is equal to yes, a call to subroutine checkmesh will
377 look for errors in the mesh, superimposed points, etc.""",
379 # -----------------------------------
380 MAXIMUM_NUMBER_OF_BOUNDARIES = SIMP(statut ='f',
381 # -----------------------------------
384 fr = """ nombre maximal de frontieres differentes dans le maillage. Sert au
385 dimensionnement de la memoire, a augmenter si necessaire""",
386 ang = """ maximal number of boundaries in the mesh. Used for dimensioning
387 arrays. Can be increased if needed""",
389 # -----------------------------------
390 MAXIMUM_NUMBER_OF_SOURCES = SIMP(statut ='f',
391 # -----------------------------------
394 fr = """ nombre maximal de points sources dans le maillage. Sert au
395 dimensionnement de la memoire, a augmenter si necessaire""",
396 ang = """ maximal number of punctual sources in the mesh. Used for dimensioning
397 arrays. Can be increased if needed""",
399 # -----------------------------------
400 MAXIMUM_NUMBER_OF_TRACERS = SIMP(statut ='f',
401 # -----------------------------------
404 fr = """ nombre maximal de traceurs. Sert au dimensionnement de la memoire, a
405 augmenter si necessaire""",
406 ang = """ maximal number of tracers. Used for dimensioning arrays. Can be
407 increased if needed""",
409 # -----------------------------------
410 VECTOR_LENGTH = SIMP(statut ='f',
411 # -----------------------------------
414 fr = """ LONGUEUR DU VECTEUR POUR LES MACHINES VECTORIELLES""",
415 ang = """ VECTOR LENGTH ON VECTOR MACHINES""",
419 # -----------------------------------
420 RESTART = FACT(statut='o',
421 # -----------------------------------
422 # -----------------------------------
423 COMPUTATION_CONTINUED = SIMP(statut ='o',
424 # -----------------------------------
427 fr = """ Determine si le calcul en cours est independant de tout autre resultat
428 ou est une reprise effectuee a partir du resultat d''un calcul
429 precedent. NON : Il s''agit du premier passage pour ce calcul et il est
430 necessaire de definir un jeu complet de conditions initiales OUI : Il
431 s''agit d''une reprise de calcul : les conditions initiales sont
432 constituees par le dernier pas de temps du FICHIER DU CALCUL PRECEDENT
433 du fichier des parametres utilise pour soumettre le calcul. Par contre,
434 l''ensemble des donnees du fichier des parametres peuvent etre
435 redefinies ; ce qui offre la possibilite de changer par exemple, le pas
436 de temps, le modele de turbulence, le frottement, d''ajouter ou retirer
437 un traceur ... De meme, il est necessaire de definir des conditions aux
438 limites (sous-programme BORD ou valeurs placees dans le fichier des
439 parametres), qui peuvent egalement etre modifiees.""",
440 ang = """ Determines whether the computation under way is independent result or
441 is following an earlier result. NO: It is the first run for this
442 computation and a whole set of initial conditions should be defined.
443 YES: It follows a former computation: the initial conditions consist in
444 the last time step of the PREVIOUS COMPUTATION FILE in the steering file
445 used for submitting the computation. All the data from the steering file
446 may be defined once again, which provides an opportunity to change, for
447 example, the time step, the turbulence model, the friction, to add or
448 remove a tracer... It is also possible to define new boundary
451 # -----------------------------------
452 b_COMPUTATION_CONTINUEDG = BLOC(condition="COMPUTATION_CONTINUED == True",
453 # -----------------------------------
454 # -----------------------------------
455 PREVIOUS_COMPUTATION_FILE_FORMAT = SIMP(statut ='o',
456 # -----------------------------------
458 into = ['SERAFIN?','SERAFIND','MED'],
460 fr = """ Format du fichier de resultats du calcul precedent. Les valeurs
461 possibles sont : - SERAFIN : format standard simple precision pour
462 Telemac; - SERAFIND: format standard double precision pour Telemac; -
463 MED : format MED base sur HDF5""",
464 ang = """ Previous computation results file format. Possible values are: -
465 SERAFIN : classical single precision format in Telemac; - SERAFIND:
466 classical double precision format in Telemac; - MED : MED format based
469 # -----------------------------------
470 PREVIOUS_COMPUTATION_FILE = SIMP(statut ='o',
471 # -----------------------------------
472 typ = ('Fichier','All Files (*)'),
474 fr = """ Nom d''un fichier contenant les resultats d''un calcul precedent
475 realise sur le meme maillage et dont le dernier pas de temps enregistre
476 va fournir les conditions initiales pour une suite de de calcul.""",
477 ang = """ Name of a file containing the results of an earlier computation which
478 was made on the same mesh. The last recorded time step will provid the
479 initial conditions for the new computation.""",
481 # -----------------------------------
482 RECORD_NUMBER_FOR_RESTART = SIMP(statut ='o',
483 # -----------------------------------
486 fr = """ En cas de suite de calcul, numero de l''enregistrement de depart dans
487 le fichier du calcul precedent. 0 signifie qu''on prend le dernier
489 ang = """ In case of COMPUTATION CONTINUED, record number to start from in the
490 PREVIOUS COMPUTATION FILE""",
493 # -----------------------------------
494 INITIAL_TIME_SET_TO_ZERO = SIMP(statut ='o',
495 # -----------------------------------
498 fr = """ Remet le temps a zero en cas de suite de calcul""",
499 ang = """ Initial time set to zero in case of restart""",
502 # -----------------------------------
503 OUTPUT_FILES = FACT(statut='o',
504 # -----------------------------------
505 # -----------------------------------
506 RESULTS_FILES = FACT(statut='o',
507 # -----------------------------------
508 # -----------------------------------
509 NUMBER_OF_FIRST_TIME_STEP_FOR_GRAPHIC_PRINTOUTS = SIMP(statut ='o',
510 # -----------------------------------
513 fr = """ Determine le nombre de pas de temps a partir duquel debute l''ecriture
514 des resultats dans le FICHIER DES RESULTATS.""",
515 ang = """ Determines the number of time steps after which the results are first
516 written into the RESULTS FILE.""",
518 # -----------------------------------
519 GRAPHIC_PRINTOUT_PERIOD = SIMP(statut ='o',
520 # -----------------------------------
523 fr = """ Determine la periode en nombre de pas de temps d''impression des
524 VARIABLES POUR LES SORTIES GRAPHIQUES (voir ce mot-cle) dans le FICHIER
526 ang = """ Determines, in number of time steps, the printout period for the
527 VARIABLES FOR GRAPHIC PRINTOUTS in the RESULTS FILE.""",
529 # -----------------------------------
530 VARIABLES_FOR_GRAPHIC_PRINTOUTS = SIMP(statut ='o',
531 # -----------------------------------
532 typ = 'TXM', min=0, max='**',
533 into = ["velocity along x axis (m/s)","velocity along y axis (m/s)","wave celerity (m/s)","water depth (m)","free surface elevation (m)","bottom elevation (m)","Froude number","scalar flowrate of fluid (m2/s)","tracer 1 etc.","turbulent kinetic energy in k-epsilon model (J/kg)","dissipation of turbulent energy (W/kg)","turbulent viscosity (m2/s)","flowrate along x axis (m2/s)","flowrate along y axis (m2/s)","scalar velocity (m/s)","wind along x axis (m/s)","wind along y axis (m/s)","air pressure (Pa)","friction coefficient","drift along x (m)","drift along y (m)","Courant number ","supplementary variable N","supplementary variable O","supplementary variable R","supplementary variable Z","maximum elevation","time of maximum elevation","maximum velocity","time of maximum velocity","friction velocity","gradient 1, etc. "],
534 defaut = ["velocity along x axis (m/s)","velocity along y axis (m/s)","water depth (m)","bottom elevation (m)"],
535 fr = """ Noms des variables que l''utilisateur veut ecrire dans le fichier des
536 resultats. Chaque variable est representee par une lettre. Le choix des
537 separateurs est libre. Les possibilites offertes sont les suivantes :
538 - U : vitesse suivant l''axe des x (m/s),
539 - V : vitesse suivant l''axe des y (m/s),
540 - C : celerite des ondes (m/s),
541 - H : hauteur d''eau (m),
542 - S : cote de surface libre (m),
543 - B : cote du fond (m),
544 - F : nombre de Froude,
545 - Q : debit scalaire du fluide (m2/s),
546 - Tn: traceur, avec n le numero du traceur,
547 - K : energie turbulente du modele k-epsilon (J/kg),
548 - E : dissipation de l''energie turbulente (W/kg),
549 - D : viscosite turbulente du modele k-epsilon (m2/s),
550 - I : debit suivant l''axe des x (m2/s),
551 - J : debit suivant l''axe des y (m2/s),
552 - M : vitesse scalaire (m/s),
553 - X : vent suivant l''axe des x (m/s),
554 - Y : vent suivant l''axe des y (m/s),
555 - P : pression atmospherique (Pa),
556 - W : coefficient de frottement sur le fond,
557 - A : derive en x (m),
558 - G : derive en y (m),
559 - L : coefficient de frottement sur le fond,
560 - Gn: gradient differencie, avec n le numero de reference du gradient.
561 L''utilisateur dispose egalement de 4 champs libres, qu''il peut
562 utiliser pour ecrire dans le fichier des resultats des variables qu''il
563 cree lui-meme. Ces variables propres a l''utlisateur doivent etre
564 calculees dans le sous-programme PRERES et le nom que l''on desire leur
565 donner doit etre ecrit dans le sous-programme NOMVAR. Ces 7 champs sont
567 - N, O, R, Z qui correspondent aux tableaux PRIVE(1,1), PRIVE(1,2),
568 PRIVE(1,3), PRIVE(1,4).
569 A la difference des variables precedentes, celles-ci sont conservees
570 dans tout le programme, et peuvent donc etre reutilisees. Dans ce
571 dernier cas ne pas oublier de donner une taille suffisante au tableau
572 PRIVE (dans le programme principal). Il est ainsi possible de limiter,
573 par exemple, la taille des fichiers de resultats pour de tres gros
574 calculs. Cependant, il faut etre conscient du fait que, dans
575 l''eventualite d''une reprise de calcul, le code doit disposer, dans le
576 fichier des resultats, des informations necessaires a sa poursuite, a
578 - les vitesses U et V,
579 - les hauteurs d''eau H,
580 - les cotes du fond B.
581 Toutefois, TELEMAC peut recalculer certaines de ces variables a
582 partir d''autres qui lui seront fournies (par exemple, il recalculera H
583 a partir de S et B).""",
584 ang = """ Names of variables the user wants to write into the results file. Each
585 variable is represented by a letter. The separators can be freely
586 selected. The available capabilities are as follows:
587 - U : velocity along x axis (m/s),
588 - V : velocity along y axis (m/s),
589 - C : wave celerity (m/s),
590 - H : water depth (m),
591 - S : free surface elevation (m),
592 - B : bottom elevation (m),
594 - Q : scalar flowrate of fluid (m2/s),
595 - Tn : tracer, with n the tracer number,
596 - K : turbulent kinetic energy in k-epsilon model (J/kg),
597 - E : dissipation of turbulent energy (W/kg),
598 - D : turbulent viscosity of k-epsilon model (m2/s),
599 - I : flowrate along x axis (m2/s),
600 - J : flowrate along y axis (m2/s),
601 - M : scalar velocity (m/s),
602 - X : wind along x axis (m/s) Y : wind along y axis (m/s),
603 - P : air pressure (Pa),
604 - W : friction coefficient ,
607 - L : nombre de courant,
608 - Gn : differentiated gradient, with n the gradient reference number.
609 Four other variables are also made available to the
610 user who may use them for writing into the file the results of variables
611 he creates himself. These user-specific variables should be computed in
612 the subroutine PRERES and their desired name should be written into the
613 subroutine NOMVAR. These seven variables are as follows:
615 which correspond to arrays PRIVE(1,1) up to PRIVE(1, Unlike the
616 preceding variables, they are preserved throughout the program, so that
617 they can be used again.
618 In the latter case, do not forget to provide the
619 array PRIVE with sufficiently large dimensions (in FORTRAN file). With
620 this key-word, one can limit the size of the RESULTS FILE. It should be
621 kept in mind, however, that if a computation has to be continued, the
622 RESULTS FILE should contain the appropriate information for running the
624 - velocities U and V,
626 - bottom elevations B.
627 TELEMAC, however, can compute some of these variables from others for
628 example, it will compute H from S and B.""",
630 # -----------------------------------
631 NUMBER_OF_PRIVATE_ARRAYS = SIMP(statut ='o',
632 # -----------------------------------
635 fr = """ Nombre de tableaux mis a disposition de l utilisateur""",
636 ang = """ Number of arrays for own user programming""",
638 # -----------------------------------
639 NAMES_OF_PRIVATE_VARIABLES = SIMP(statut ='f',
640 # -----------------------------------
641 typ = 'TXM', min= 2, max= 2,
642 fr = """ Noms des variables privees en 32 caracteres, 16 pour le nom 16 pour
643 l''unite. Elles correspondent au bloc PRIVE et peuvent etre lues dans le
644 fichier de geometrie si elles y sont presentes avec leur nom""",
645 ang = """ Name of private variables in 32 characters, 16 for the name, 16 for
646 the unit. They are stored in the block PRIVE and can be read in the
647 geometry file if they are here with their name""",
649 # -----------------------------------
650 RESULTS_FILE_FORMAT = SIMP(statut ='o',
651 # -----------------------------------
653 into = ['SERAFIN?','SERAFIND','MED'],
655 fr = """ Format du fichier de resultats. Les valeurs possibles sont : - SERAFIN
656 : format standard simple precision pour Telemac; - SERAFIND: format
657 standard double precision pour Telemac; - MED : format MED base sur
659 ang = """ Results file format. Possible values are: - SERAFIN : classical single
660 precision format in Telemac; - SERAFIND: classical double precision
661 format in Telemac; - MED : MED format based on HDF5""",
663 # -----------------------------------
664 RESULTS_FILE = SIMP(statut ='o',
665 # -----------------------------------
666 typ = ('Fichier','All Files (*)','Sauvegarde'),
668 fr = """ Nom du fichier dans lequel seront ecrits les resultats du calcul avec
669 la periodicite donnee par le mot cle PERIODE POUR LES SORTIES
671 ang = """ Name of the file into which the computation results shall be written,
672 the periodicity being given by the key-word: GRAPHIC PRINTOUT PERIOD.""",
674 # -----------------------------------
675 BINARY_RESULTS_FILE_FORMAT = SIMP(statut ='f',
676 # -----------------------------------
678 into = ['BIN','SERAFIN','SERAFIND','MED'],
680 fr = """ Format du fichier de resultats binaire. Les valeurs possibles sont : -
681 SERAFIN : format standard simple precision pour Telemac; - SERAFIND:
682 format standard double precision pour Telemac; - MED : format MED base
684 ang = """ Binary results file format. Possible values are: - SERAFIN : classical
685 single precision format in Telemac; - SERAFIND: classical double
686 precision format in Telemac; - MED : MED format based on HDF5""",
688 # -----------------------------------
689 BINARY_RESULTS_FILE = SIMP(statut ='f',
690 # -----------------------------------
691 typ = ('Fichier','All Files (*)','Sauvegarde'),
693 fr = """ Fichier de resultats code en binaire mis a la disposition de
694 l''utilisateur. Les resultats a placer dans ce fichier seront a ecrire
696 ang = """ Additional binary-coded result file made available to the user. The
697 results to be entered into this file shall be written on channel 28.""",
699 # -----------------------------------
700 FORMATTED_RESULTS_FILE = SIMP(statut ='f',
701 # -----------------------------------
702 typ = ('Fichier','All Files (*)','Sauvegarde'),
704 fr = """ Fichier de resultats formate mis a la disposition de l''utilisateur.
705 Les resultats a placer dans ce fichier seront a ecrire sur le canal 29.""",
706 ang = """ Formatted file of results made available to the user. The results to
707 be entered into this file shall be written on channel 29.""",
710 # -----------------------------------
711 CONTROL_SECTION = FACT(statut='f',
712 # -----------------------------------
713 # -----------------------------------
714 CONTROL_SECTIONS = SIMP(statut ='f',
715 # -----------------------------------
716 typ = Tuple(2), min= 2, max='**' ,validators = VerifTypeTuple(('I','I')),
717 fr = """ Couples de points (numeros globaux dans le maillage) entre lesquels
718 les debits instantanes et cumules seront donnes.""",
719 ang = """ Couples of points (global numbers in the mesh) defining sections where
720 the instantaneous and cumulated discharges will be given""",
722 # -----------------------------------
723 PRINTING_CUMULATED_FLOWRATES = SIMP(statut ='o',
724 # -----------------------------------
727 fr = """ IMPRESSION DU FLUX CUMULE A TRAVERS LES SECTIONS DE CONTROLE""",
728 ang = """ PRINTING THE CUMULATED FLOWRATES THROUGH CONTROL SECTIONS""",
730 # -----------------------------------
731 COMPATIBLE_COMPUTATION_OF_FLUXES = SIMP(statut ='o',
732 # -----------------------------------
735 fr = """ FLUX A TRAVERS LES SECTIONS DE CONTROLE, CALCUL COMPATIBLE AVEC
736 L''IMPERMEABILITE SOUS FORME FAIBLE""",
737 ang = """ FLOWRATES THROUGH CONTROL SECTIONS, COMPUTATION COMPATIBLE WITH THE
738 WEAK FORMULATION OF NO-FLUX BOUNDARY CONDITION""",
740 # -----------------------------------
741 SECTIONS_INPUT_FILE = SIMP(statut ='f',
742 # -----------------------------------
743 typ = ('Fichier','All Files (*)'),
745 fr = """ sections input file, partitioned""",
746 ang = """ sections input file, partitioned""",
748 # -----------------------------------
749 SECTIONS_OUTPUT_FILE = SIMP(statut ='f',
750 # -----------------------------------
751 typ = ('Fichier','All Files (*)','Sauvegarde'),
753 fr = """ sections output file, written by the master""",
754 ang = """ sections output file, written by the master""",
756 # -----------------------------------
757 FLUXLINE = SIMP(statut ='f',
758 # -----------------------------------
762 ang = """Use Fluxline to compute flux over lines""",
764 # -----------------------------------
765 FLUXLINE_INPUT_FILE = SIMP(statut ='f',
766 # -----------------------------------
767 typ = ('Fichier','All Files (*)'),
769 fr = """Nom du fichier de fluxline, avec des donnees sur les sections""",
770 ang = """Name of the Fluxline file, with data on cross-sections""",
773 # -----------------------------------
774 LISTING = FACT(statut='o',
775 # -----------------------------------
776 # -----------------------------------
777 NUMBER_OF_FIRST_TIME_STEP_FOR_LISTING_PRINTOUTS = SIMP(statut ='f',
778 # -----------------------------------
781 fr = """ Determine le nombre de pas de temps a partir duquel debute l''ecriture
782 des resultats dans le listing.""",
783 ang = """ Determines the number of time steps after which the results are first
784 written into the listing.""",
786 # -----------------------------------
787 LISTING_PRINTOUT_PERIOD = SIMP(statut ='o',
788 # -----------------------------------
791 fr = """ Determine la periode en nombre de pas de temps d''impression des
792 VARIABLES A IMPRIMER (voir ce mot-cle) Pour la mise au point, il faut
793 savoir que la sortie des resultats est effectuee systematiquement sur le
794 fichier de retour d''execution du code (actuellement accessible par le
795 menu 3.f de SPF sur IBM, et dans le fichier !CAS.SORTIE sur station de
797 ang = """ Determines, in number of time steps, the printout period of the
798 VARIABLES TO BE PRINTED The results are systematically printed out on
799 the listing file (file CAS.SORTIE at the workstation).""",
801 # -----------------------------------
802 LISTING_FOR_PRINTOUT_PERIOD = SIMP(statut ='f',
803 # -----------------------------------
806 fr = """ Determine la periode en nombre de pas de temps d''impression des
807 VARIABLES A IMPRIMER (voir ce mot-cle) Pour la mise au point, il faut
808 savoir que la sortie des resultats est effectuee systematiquement sur le
809 fichier de retour d''execution du code (actuellement accessible par le
810 menu 3.f de SPF sur IBM, et dans le fichier !CAS.SORTIE sur station de
812 ang = """ Determines, in number of time steps, the printout period of the
813 VARIABLES TO BE PRINTED The results are systematically printed out on
814 the listing file (file CAS.SORTIE at the workstation).""",
816 # -----------------------------------
817 LISTING_PRINTOUT = SIMP(statut ='o',
818 # -----------------------------------
821 fr = """ Sortie des resultats sur support papier. Si l''on met NON le listing
822 ne contient que l''entete et la mention FIN NORMALE DU PROGRAMME
823 Commande a eviter""",
824 ang = """ Result printout on hard copy. When NO is selected, the listing only
825 includes the heading and the phrase "NORMAL END OF PROGRAM" In addition,
826 the options MASS BALANCE and VALIDATION are inhibited. Not recommended
829 # -----------------------------------
830 VARIABLES_TO_BE_PRINTED = SIMP(statut ='o',
831 # -----------------------------------
832 typ = 'TXM', min=0, max='**',
833 into = ["velocity along x axis (m/s)","velocity along y axis (m/s)","wave celerity (m/s)","water depth (m)","free surface elevation (m)","bottom elevation (m)","Froude number","scalar flowrate of fluid (m2/s)","tracer 1, etc.","turbulent kinetic energy in k-epsilon model (J/kg)","dissipation of turbulent energy (W/kg)","turbulent viscosity of k-epsilon model (m2/s)","flowrate along x axis (m2/s)","flowrate along y axis (m2/s)","scalar velocity (m/s)","wind along x axis (m/s)","wind along y axis (m/s)","air pressure (Pa)","friction coefficient","drift along x (m)","drift along y (m)","nombre de courants ","supplementary variable N","supplementary variable O","supplementary variable R","supplementary variable Z","gradient 1, etc."],
834 fr = """ Nom des variables que l''utilisateur desire ecrire a l''ecran. Meme
835 possibilites que pour les sorties graphiques.""",
838 # -----------------------------------
839 MASS_BALANCE = SIMP(statut ='o',
840 # -----------------------------------
843 fr = """ Determine si l''on effectue ou non le bilan de masse sur le domaine.
844 Cette procedure calcule a chaque pas de temps : - les flux aux entrees
845 et sorties du domaine; - le flux global a travers l''ensemble des parois
846 du domaine (liquides ou solides) - l''erreur relative sur la masse pour
847 ce pas de temps. En fin de listing, on trouve l''erreur relative sur la
848 masse pour l''ensemble du calcul. Il ne s''agit que d''un calcul
849 indicatif car il n''existe pas d''expression compatible du debit en
850 formulation c,u,v.""",
851 ang = """ Determines whether a check of the mass-balance over the domain is
852 mader or not. This procedures computes the following at each time step:
853 the domain inflows and outflows, the overall flow across all the
854 boundaries, the relative error in the mass for that time step. The
855 relative error in the mass over the whole computation can be found at
856 the end of the listing.""",
858 # -----------------------------------
859 INFORMATION_ABOUT_SOLVER = SIMP(statut ='f',
860 # -----------------------------------
863 fr = """ Donne a chaque pas de temps le nombre d''iterations necessaires a la
864 convergence du solveur de l''etape de propagation.""",
865 ang = """ if YES, prints the number of iterations that have been necessar to get
866 the solution of the linear system.""",
868 # -----------------------------------
869 LIST_OF_POINTS = SIMP(statut ='f',
870 # -----------------------------------
871 typ = Tuple(2), min= 2, max='**' ,validators = VerifTypeTuple(('I','I')),
872 fr = """ Liste de points remarquables pour les impressions""",
873 ang = """ List of remarkable points for printouts""",
875 # -----------------------------------
876 NAMES_OF_POINTS = SIMP(statut ='f',
877 # -----------------------------------
878 typ = 'TXM', min= 2, max= 2,
879 fr = """ Noms des points remarquables pour les impressions""",
880 ang = """ Names of remarkable points for printouts""",
883 # -----------------------------------
884 FOURIER = FACT(statut='f',
885 # -----------------------------------
886 # -----------------------------------
887 FOURIER_ANALYSIS_PERIODS = SIMP(statut ='o',
888 # -----------------------------------
889 typ = Tuple(2), min= 2, max='**' ,validators = VerifTypeTuple(('R','R')),
890 fr = """ Liste des periodes que l''on veut analyser""",
891 ang = """ List of periods to be analysed""",
893 # -----------------------------------
894 TIME_RANGE_FOR_FOURIER_ANALYSIS = SIMP(statut ='o',
895 # -----------------------------------
896 typ = 'R', min= 2, max= 2,
898 fr = """ Pour le calcul du marnage et de la phase de la maree""",
899 ang = """ For computing tidal range and phase of tide""",
904 # -----------------------------------------------------------------------
905 HYDRO = PROC(nom= "HYDRO",op = None,
906 # -----------------------------------------------------------------------
907 UIinfo = {"groupes": ("CACHE")},
912 # -----------------------------------
913 BOUNDARY_CONDITIONS = FACT(statut='o',
914 # PNPN --> Attention aux noms cf generator
915 # -----------------------------------
916 # -----------------------------------
917 LIQUID_BOUNDARIES = FACT(statut ='f', min = 1, max="**",
918 # -----------------------------------
919 # -----------------------------------
920 # BOUNDARY_NAME = SIMP(statut ='o', typ = 'TXM',),
921 # -----------------------------------
922 # -----------------------------------
923 BOUNDARY_TYPE = SIMP(statut ='o', typ = 'TXM', into = ['Prescribed Flowrates', 'Prescribed Elevations', 'Prescribed Velocity'],),
924 # -----------------------------------
926 # ------------------------------------
927 b_Elevations = BLOC (condition = "BOUNDARY_TYPE == 'Prescribed Elevations'",
928 # ------------------------------------
930 # -----------------------------------
931 PRESCRIBED_ELEVATIONS = SIMP(statut ='o',
932 # -----------------------------------
934 fr = """ Valeurs des cotes imposees aux frontieres liquides entrantes. Lire la
935 partie du mode d''emploi consacree aux conditions aux limites""",
936 ang = """ Values of prescribed elevations at the inflow boundaries. The section
937 about boundary conditions is to be read in the manual""",
940 # ------------------------------------
941 b_Flowrates = BLOC (condition = "BOUNDARY_TYPE == 'Prescribed Flowrates'",
942 # ------------------------------------
943 # -----------------------------------
944 PRESCRIBED_FLOWRATES = SIMP(statut ='o',
945 # -----------------------------------
947 fr = """ Valeurs des debits imposes aux frontieres liquides entrantes. Lire la
948 partie du mode d''emploi consacree aux conditions aux limites""",
949 ang = """ Values of prescribed flowrates at the inflow boundaries. The section
950 about boundary conditions is to be read in the manual""",
953 b_Velocity = BLOC (condition = "BOUNDARY_TYPE == 'Prescribed Velocity'",
954 # -----------------------------------
955 PRESCRIBED_VELOCITIES = SIMP(statut ='o',
956 # -----------------------------------
958 fr = """ Valeurs des vitesses imposees aux frontieres liquides entrantes. Lire
959 la partie du mode d''emploi consacree aux conditions aux limites""",
960 ang = """ Values of prescribed velocities at the liquid inflow boundaries. Refer
961 to the section dealing with the boundary conditions""",
965 # -----------------------------------
966 STAGE_DISCHARGE_CURVES = SIMP(statut ='f',
967 # -----------------------------------
968 typ = 'TXM', max='**',
969 into = ["no","Z(Q)","Q(Z) not programmed"],
970 fr = """ Indique si une courbe de tarage doit etre utilisee pour une frontiere
971 0:non 1:Z(Q) 2: Q(Z) (2 non programme)""",
972 ang = """ Says if a discharge-elevation curve must be used for a given boundary
973 :NO 1:Z(Q) 2: Q(Z) (2 not programmed)""",
975 # -----------------------------------
976 b_STAGE_DISCHARGE_CURVESG = BLOC(condition="STAGE_DISCHARGE_CURVES != 'no'",
977 # -----------------------------------
978 # -----------------------------------
979 STAGE_DISCHARGE_CURVES_FILE = SIMP(statut ='f',
980 # -----------------------------------
981 typ = ('Fichier','All Files (*)'),
983 fr = """ Nom du fichier contenant les courbes de tarage""",
984 ang = """ Name of the file containing stage-discharge curves""",
987 # -----------------------------------
988 VELOCITY_PROFILES = SIMP(statut ='f',
989 # -----------------------------------
990 typ = 'TXM', max='**',
991 into = ["constant normal profile","u and v given in the conlim file","normal velocity given in ubor in the conlim file","velocity proportional to square root of depth","velocity proportional to square root of depth, variant"],
992 fr = """ 1:profil normal constant 2:u et v donnes dans le fichier conlim
993 3:vitesse normale donnee dans ubor dans le fichier conlim 4:profil en
994 racine de la profondeur 5:profil en racine de la profondeur, variante""",
995 ang = """ 1:constant normal profile 2:u and v given in the conlim file 3:normal
996 velocity given in ubor in the conlim file 4:sqrt(depth) profile
997 5:sqrt(depth) profile, variant""",
999 # -----------------------------------
1000 OPTION_FOR_LIQUID_BOUNDARIES = SIMP(statut ='f',
1001 # -----------------------------------
1002 typ = 'TXM', max='**',
1003 into = ["classical","Thompson method based on characteristics"],
1004 fr = """ On donne 1 entier par frontiere liquide 1 : conditions aux limites
1005 classiques 2 : methode de Thompson avec calcul de caracteristiques""",
1006 ang = """ One integer per liquid boundary is given 1 : classical boundary
1007 conditions 2 : Thompson method based on characteristics""",
1009 # -----------------------------------
1010 LIQUID_BOUNDARIES_FILE = SIMP(statut ='f',
1011 # -----------------------------------
1012 typ = ('Fichier','All Files (*)'),
1014 fr = """ Fichier de variations en temps des conditions aux limites. Les donnees
1015 de ce fichier seront a lire sur le canal 12.""",
1016 ang = """ Variations in time of boundary conditions. Data of this file are read
1019 # -----------------------------------
1020 ELEMENTS_MASKED_BY_USER = SIMP(statut ='o',
1021 # -----------------------------------
1024 fr = """ SI OUI REMPLIR LE SOUS-PROGRAMME MASKOB""",
1025 ang = """ IF YES REWRITE SUBROUTINE MASKOB""",
1027 # -----------------------------------
1028 b_ELEMENTS_MASKED_BY_USERG = BLOC(condition="ELEMENTS_MASKED_BY_USER == True",
1029 # -----------------------------------
1030 # -----------------------------------
1031 Consigne = SIMP(statut ="o", homo="information", typ="TXM",
1032 # -----------------------------------
1033 defaut = "Rewrite subroutine maskob"),
1036 # -----------------------------------
1037 PHYSICAL_PARAMETERS_HYDRO = FACT(statut='o',
1038 # -----------------------------------
1039 # -----------------------------------
1040 FRICTION = FACT(statut='o',
1041 # -----------------------------------
1042 # -----------------------------------
1043 MAXIMUM_NUMBER_OF_FRICTION_DOMAINS = SIMP(statut ='o',
1044 # -----------------------------------
1047 fr = """ nombre maximal de zones pouvant etre definies pour le frottement. Peut
1048 etre augmente si necessaire""",
1049 ang = """ maximal number of zones defined for the friction. Could be increased
1052 # -----------------------------------
1053 FRICTION_DATA = SIMP(statut ='f',
1054 # -----------------------------------
1057 fr = """ Lois de frottements definies par zone""",
1058 ang = """ Friction law defined by area""",
1060 # -----------------------------------
1061 FRICTION_DATA_FILE = SIMP(statut ='f',
1062 # -----------------------------------
1063 typ = ('Fichier','All Files (*)'),
1065 fr = """ fichier de donnees pour le frottement""",
1066 ang = """ friction data file""",
1068 # -----------------------------------
1069 LAW_OF_BOTTOM_FRICTION = SIMP(statut ='o',
1070 # -----------------------------------
1072 into = ["NO FRICTION","HAALAND","CHEZY","STRICKLER","MANNING","NIKURADSE"],
1073 fr = """ selectionne le type de formulation utilisee pour le calcul du
1074 frottement sur le fond. Les lois possibles sont les suivantes (cf. Note
1075 de principe) : - 0 : pas de frottement sur le fond; 1 : formule de
1076 Haaland 2 : formule de Chezy 3 : formule de STRICKLER 4 : formule de
1077 MANNING 5 : formule de NIKURADSE""",
1078 ang = """ Selects the type of formulation used for the bottom friction. The
1079 possible laws are as follows (refer to the Principle note): 0: no
1080 friction against bottom, 1: Haaland''s formula 2: CHEZY''s formula 3:
1081 STRICKLER''s formula 4: MANNING''s formula 5: NIKURADSE''s formula""",
1083 # -----------------------------------
1084 b_LAW_OF_BOTTOM_FRICTIONG = BLOC(condition="LAW_OF_BOTTOM_FRICTION != 'NO FRICTION'",
1085 # -----------------------------------
1086 # -----------------------------------
1087 FRICTION_COEFFICIENT = SIMP(statut ='o',
1088 # -----------------------------------
1091 fr = """ Fixe la valeur du coefficient de frottement pour la formulation
1092 choisie. Attention; la signification de ce chiffre varie suivant la
1093 formule choisie : 1 : coefficient lineaire 2 : coefficient de Chezy 3 :
1094 coefficient de Strickler 4 : coefficient de Manning 5 : hauteur de
1095 rugosite de Nikuradse""",
1096 ang = """ Sets the value of the friction coefficient for the selected
1097 formulation. It is noteworthy that the meaning of this figure changes
1098 according to the selected formula (Chezy, Strickler, etc.) : 1 : linear
1099 coefficient 2 : Chezy coefficient 3 : Strickler coefficient 4 : Manning
1100 coefficient 5 : Nikuradse grain size""",
1103 # -----------------------------------
1104 MANNING_DEFAULT_VALUE_FOR_COLEBROOK_WHITE_LAW = SIMP(statut ='o',
1105 # -----------------------------------
1108 fr = """ valeur par defaut du manning pour la loi de frottement de
1109 Colebrook-White (loi numero 7)""",
1110 ang = """ Manning default value for the friction law of Colebrook-White (law
1113 # -----------------------------------
1114 DEPTH_IN_FRICTION_TERMS = SIMP(statut ='o',
1115 # -----------------------------------
1117 into = ["nodal","average"],
1119 fr = """ 1 : nodale 2 : moyenne""",
1120 ang = """ 1: nodal 2: average""",
1122 # -----------------------------------
1123 NON_SUBMERGED_VEGETATION_FRICTION = SIMP(statut ='o',
1124 # -----------------------------------
1127 fr = """ calcul du frottement du a la vegetation non submergee""",
1128 ang = """ friction calculation of the non-submerged vegetation""",
1130 # -----------------------------------
1131 b_NON_SUBMERGED_VEGETATION_FRICTIONG = BLOC(condition="NON_SUBMERGED_VEGETATION_FRICTION == True",
1132 # -----------------------------------
1133 # -----------------------------------
1134 DIAMETER_OF_ROUGHNESS_ELEMENTS = SIMP(statut ='o',
1135 # -----------------------------------
1138 fr = """ diametre des elements de frottements""",
1139 ang = """ diameter of roughness element""",
1141 # -----------------------------------
1142 SPACING_OF_ROUGHNESS_ELEMENTS = SIMP(statut ='o',
1143 # -----------------------------------
1146 fr = """ espacement des elements de frottement""",
1147 ang = """ spacing of rouhness element""",
1150 # -----------------------------------
1151 LAW_OF_FRICTION_ON_LATERAL_BOUNDARIES = SIMP(statut ='o',
1152 # -----------------------------------
1154 into = ["NO FRICTION","HAALAND","CHEZY","STRICKLER","MANNING","NIKURADSE","LOG LAW","COLEBROOK-WHITE"],
1155 defaut = "NO FRICTION",
1156 fr = """ selectionne le type de formulation utilisee pour le calcul du
1157 frottement sur les parois laterales. Les lois possibles sont les
1158 suivantes (cf. Note de principe) : 0 : pas de frottement 1 : lineaire 2
1159 : Chezy 3 : Strickler 4 : Manning 5 : formule de NIKURADSE 6 : loi en
1160 log 7 : Colebrook-White""",
1161 ang = """ Selects the type of formulation used for the friction on lateral
1162 boundaries. The possible laws are as follows (refer to the Principle
1163 note): 0: no friction 1: linear 2: Chezy 3: Strickler 4: Manning 5:
1164 NIKURADSE''s formula 6 : law log 7 : Colebrook-White""",
1166 # -----------------------------------
1167 b_LAW_OF_FRICTION_ON_LATERAL_BOUNDARIESG = BLOC(condition="LAW_OF_FRICTION_ON_LATERAL_BOUNDARIES != 'NO FRICTION'",
1168 # -----------------------------------
1169 # -----------------------------------
1170 ROUGHNESS_COEFFICIENT_OF_BOUNDARIES = SIMP(statut ='o',
1171 # -----------------------------------
1174 fr = """ Fixe la valeur du coefficient de frottement sur les frontieres solides
1175 avec un regime turbulent rugueux sur les bords du domaine. meme
1176 convention que pour le coefficient de frottement: 1 : non programme 2 :
1177 coefficient de Chezy 3 : coefficient de Strickler 4 : coefficient de
1178 Manning 5 : hauteur de rugosite de Nikuradse""",
1179 ang = """ Sets the value of the friction coefficient of the solid boundary with
1180 the bed roughness option. Same meaning than friction coefficient""",
1183 # -----------------------------------
1184 DEFINITION_OF_ZONES = SIMP(statut ='o',
1185 # -----------------------------------
1188 fr = """ Declenche l''appel a def\_zones, pour donner un numero de zone a
1190 ang = """ Triggers the call to def\_zones to give a zone number to every point""",
1192 # -----------------------------------
1193 b_DEFINITION_OF_ZONESG = BLOC(condition="DEFINITION_OF_ZONES == True",
1194 # -----------------------------------
1195 # -----------------------------------
1196 Consigne = SIMP(statut ="o", homo="information", typ="TXM",
1197 # -----------------------------------
1198 defaut = "Rewrite subroutine def_zones"),
1200 # -----------------------------------
1201 ZONES_FILE = SIMP(statut ='f',
1202 # -----------------------------------
1203 typ = ('Fichier','All Files (*)'),
1205 fr = """ Fichier des zones avec sur chaque ligne numero de point numero de
1207 ang = """ Zones file, with on every line: point number zone number""",
1210 # -----------------------------------
1211 METEOROLOGY = FACT(statut='f',
1212 # -----------------------------------
1213 # -----------------------------------
1214 WIND = SIMP(statut ='o',
1215 # -----------------------------------
1218 fr = """ Prise en compte ou non des effets du vent.""",
1219 ang = """ Determines whether the wind effects are to be taken into account or
1222 # -----------------------------------
1223 b_WINDG = BLOC(condition="WIND == True",
1224 # -----------------------------------
1225 # -----------------------------------
1226 WIND_VELOCITY_ALONG_X = SIMP(statut ='o',
1227 # -----------------------------------
1230 fr = """ Composante de la vitesse du vent suivant l''axe des x (m/s).""",
1231 ang = """ Wind velocity, component along x axis (m/s).""",
1233 # -----------------------------------
1234 WIND_VELOCITY_ALONG_Y = SIMP(statut ='o',
1235 # -----------------------------------
1238 fr = """ Composante de la vitesse du vent suivant l''axe des y (m/s).""",
1239 ang = """ Wind velocity, component along y axis (m/s).""",
1241 # -----------------------------------
1242 THRESHOLD_DEPTH_FOR_WIND = SIMP(statut ='o',
1243 # -----------------------------------
1246 fr = """ Retire la force due au vent dans les petites profondeurs""",
1247 ang = """ Wind is not taken into account for small depths""",
1249 # -----------------------------------
1250 COEFFICIENT_OF_WIND_INFLUENCE = SIMP(statut ='o',
1251 # -----------------------------------
1254 fr = """ Fixe la valeur du coefficient d''entrainement du vent (cf. Note de
1256 ang = """ Sets the value of the wind driving coefficient. Refer to principle
1259 # -----------------------------------
1260 OPTION_FOR_WIND = SIMP(statut ='o',
1261 # -----------------------------------
1263 into = ["constant in time and space","variable in time given by formated file","variable in time and space given by formated file"],
1264 defaut = "constant in time and space",
1265 fr = """ donne les options pour introduire le vent:
1266 1: constant en temps et en espace (donne par le mot cle VITESSE ET
1268 2: variable en temps donne par fichier formate
1269 3: variable en temps et en espace donne par fichier formate""",
1270 ang = """ gives option for managing the wind:
1271 1: constant in time and space, given by keyword SPEED AND DIRECTION OF
1273 2: variable in time and (constant in space), given by formated file
1274 3: variable in time and space""",
1276 # -----------------------------------
1277 b_OPTION_FOR_WINDG = BLOC(condition="OPTION_FOR_WIND == 'constant in time and space'",
1278 # -----------------------------------
1279 # -----------------------------------
1280 SPEED_AND_DIRECTION_OF_WIND = SIMP(statut ='o',
1281 # -----------------------------------
1282 typ = 'R', min= 2, max= 2,
1284 fr = """ Donne la vitesse et la direction (en degres de 0 a 360, 0 etant y=0 et
1285 x=+inf) du vent lorsqu ils sont consant en temps et en espace (mot cle
1286 OPTION DU VENT = 1)""",
1287 ang = """ gives the speed and direction (degre (from 0 to 360), 0 given y=0 anx
1288 x=+infinity) when they are constant in time and space (keyword OPTION
1292 # -----------------------------------
1293 b_OPTION_FOR_WINDH = BLOC(condition="OPTION_FOR_WIND == 'variable in time given by formated file' or OPTION_FOR_WIND == 'variable in time and space given by formated file'",
1294 # -----------------------------------
1295 # -----------------------------------
1296 Consigne = SIMP(statut ="o", homo="information", typ="TXM",
1297 # -----------------------------------
1298 defaut = "Give the formatted file 3"),
1301 # -----------------------------------
1302 AIR_PRESSURE = SIMP(statut ='o',
1303 # -----------------------------------
1306 fr = """ Permet de decider si l''on prend ou non en compte l''influence d''un
1307 champ de pression.""",
1308 ang = """ Provided to decide whether the influence of an atmosphere field is
1309 taken into account or not.""",
1311 # -----------------------------------
1312 b_AIR_PRESSUREG = BLOC(condition="AIR_PRESSURE == True",
1313 # -----------------------------------
1314 # -----------------------------------
1315 VALUE_OF_ATMOSPHERIC_PRESSURE = SIMP(statut ='o',
1316 # -----------------------------------
1319 fr = """ donne la valeur de la pression atmospherique lorsquelle est constante
1320 en temps et en espace""",
1321 ang = """ gives the value of atmospheric pressure when it is contant in time and
1325 # -----------------------------------
1326 RAIN_OR_EVAPORATION = SIMP(statut ='o',
1327 # -----------------------------------
1330 fr = """ Pour ajouter un apport ou une perte d''eau en surface. Voir le mot-cle
1331 PLUIE OU EVAPORATION EN MM PAR JOUR""",
1332 ang = """ to add or remove water at the free surface. See the key-word RAIN OR
1333 EVAPORATION IN MM PER DAY""",
1335 # -----------------------------------
1336 b_RAIN_OR_EVAPORATIONG = BLOC(condition="RAIN_OR_EVAPORATION == True",
1337 # -----------------------------------
1338 # -----------------------------------
1339 RAIN_OR_EVAPORATION_IN_MM_PER_DAY = SIMP(statut ='o',
1340 # -----------------------------------
1343 fr = """ Pour ajouter un apport ou une perte d''eau en surface""",
1344 ang = """ to add or remove water at the free surface""",
1347 # -----------------------------------
1348 RAINFALL_RUNOFF_MODEL = SIMP(statut ='f',
1349 # -----------------------------------
1351 into = ["No infiltration","CN runoff model"],
1352 defaut = "No infiltration",
1353 fr = """Option pour modele pluie-debit. Les options disponibles sont:
1354 0 : Pas d infiltration (fonction de base)
1355 1 : Modele CN (Curve Number du SCS)""",
1356 ang = """Option for the rainfall-runoff model. Available options are:
1358 1 : CN runoff model (Curve Number method of the SCS)""",
1360 # -----------------------------------
1361 ANTECEDENT_MOISTURE_CONDITIONS = SIMP(statut ='f',
1362 # -----------------------------------
1365 fr = """Donne les conditions d humidite precedant un episode de pluie pour
1366 le modele CN du SCS. Les options disponibles sont:
1367 1 : conditions precedentes seches
1368 2 : conditions precedentes normales
1369 3 : conditions prcedentes mouillees
1370 ce mot cle est uniquement utile pour le modele pluie-débit 1 (CN)""",
1371 ang = """Gives the antecedent moisture conditions before a rainfall
1372 event for the SCS CN runoff model. Available options are:
1373 1 : dry antecedent conditions
1374 2 : normal antecedent conditions
1375 3 : wet antecedent conditions
1376 this keyword is only usefull for runoff model 1 (SCS CN model)""",
1378 # -----------------------------------
1379 DURATION_OF_RAIN_OR_EVAPORATION_IN_HOURS = SIMP(statut ='f',
1380 # -----------------------------------
1383 fr = """Donne la duree de la pluie en heure, par defaut pluie infinie""",
1384 ang = """Gives the duration of the rain in hour,
1385 default value is infinite""",
1387 # -----------------------------------
1388 ASCII_ATMOSPHERIC_DATA_FILE = SIMP(statut ='f',
1389 # -----------------------------------
1390 typ = ('Fichier','All Files (*)'),
1392 fr = """Fichier de donnees en ascii contenant les informations
1393 atmospheriques variables en temps""",
1394 ang = """Ascii data file containing the atmospheric data varying in
1397 # -----------------------------------
1398 BINARY_ATMOSPHERIC_DATA_FILE = SIMP(statut ='f',
1399 # -----------------------------------
1400 typ = ('Fichier','All Files (*)'),
1402 fr = """Fichier de donnees code en binaire contenant les informations
1403 atmospheriques variables en temps et en espace sur le maillage""",
1404 ang = """Binary-coded data file containing the atmospheric data varying in
1405 time and space on the mesh""",
1407 # -----------------------------------
1408 BINARY_ATMOSPHERIC_DATA_FILE_FORMAT = SIMP(statut ='f',
1409 # -----------------------------------
1411 into = ['SERAFIN?','SERAFIND','MED'],
1412 defaut = 'SERAFIN?',
1413 fr = """Format du fichier binaire de donn\E9es atmospheriques.
1414 Les valeurs possibles sont :
1415 - SERAFIN : format standard simple precision pour Telemac;
1416 - SERAFIND: format standard double precision pour Telemac;
1417 - MED : format MED base sur HDF5""",
1418 ang = """Binary atmospheric file format.
1419 Possible values are:
1420 - SERAFIN : classical single precision format in Telemac;
1421 - SERAFIND: classical double precision format in Telemac;
1422 - MED : MED format based on HDF5""",
1424 # -----------------------------------
1425 OPTION_FOR_INITIAL_ABSTRACTION_RATIO = SIMP(statut ='f',
1426 # -----------------------------------
1429 fr = """ Donne le ratio entre pertes initiales IA et la retention potenti
1430 maximale S pour le modele pluie-debit SCS CN. Les options disponibles so
1431 1 : IA/S = 0.2 (methode standard) 2 : IA/S = 0.05 (methode revisee,
1432 cf. Woodward, Hawkins et al. 2003. A cette option les coefficients CN
1433 fournis en entree sont alors automatiquement corriges, cf. manuel
1434 utilisateur). Ce mot cle est uniquement utile pour le modele pluie-debit
1436 ang = """ Gives the ratio for Initial Abstraction to Maximal Potential Retention
1437 S for the SCS CN runoff model. Available options are: 1 : IA/S = 0.2
1438 (standard method) 2 : IA/S = 0.05 (revised method, see Woodward, Hawkins
1439 et al. 2003. With this option the CN values given in input are
1440 automatically convers see user manual). This keyword is only useful for
1441 runoff model 1 (SCS CN model)""",
1444 # -----------------------------------
1445 WAVE = FACT(statut='f',
1446 # -----------------------------------
1447 # -----------------------------------
1448 WAVE_DRIVEN_CURRENTS = SIMP(statut ='o',
1449 # -----------------------------------
1452 fr = """ Active la prise en compte des courants de houle""",
1453 ang = """ Wave driven currents are taken into account.""",
1455 # -----------------------------------
1456 b_WAVE_DRIVEN_CURRENTSG = BLOC(condition="WAVE_DRIVEN_CURRENTS == True",
1457 # -----------------------------------
1458 # -----------------------------------
1459 RECORD_NUMBER_IN_WAVE_FILE = SIMP(statut ='o',
1460 # -----------------------------------
1463 fr = """ Numero d enregistrement dans le fichier des courants de houle""",
1464 ang = """ Record number to read in the wave driven currents file""",
1467 # -----------------------------------
1468 WAVE_ENHANCED_FRICTION_FACTOR = SIMP(statut ='f',
1469 # -----------------------------------
1472 fr = """ Active la prise en compte des interactions non-lineaires entre la
1473 houle et les courant pour le calcul du courant de houle (cf OConnor and
1474 Yoo, 1988, Coast Eng.12.)""",
1475 ang = """ Wave friction enhancement for the calculation of the wave generated
1476 longshore current (cf OConnor and Yoo, 1988, Coast Eng.12.)""",
1479 # -----------------------------------
1480 ESTIMATION = FACT(statut='f',
1481 # -----------------------------------
1482 # -----------------------------------
1483 PARAMETER_ESTIMATION = SIMP(statut ='o',
1484 # -----------------------------------
1486 into = ['','FRICTION','FROTTEMENT, STEADY'],
1488 fr = """ Liste des parametres a estimer, choix : FROTTEMENT ou FROTTEMENT,
1490 ang = """ List of parameter to be estimated, choice : FRICTION or FRICTION,
1493 # -----------------------------------
1494 COST_FUNCTION = SIMP(statut ='f',
1495 # -----------------------------------
1497 into = ["Computed with h,u,v","Computed with c,u,v"],
1498 defaut = "Computed with h,u,v",
1499 fr = """ 1 : calculee sur h, u , v 2 : calculee avec c, u , v""",
1500 ang = """ 1: computed with h, u , v 2: computed with c, u , v""",
1502 # -----------------------------------
1503 IDENTIFICATION_METHOD = SIMP(statut ='o',
1504 # -----------------------------------
1506 into = ["list of tests","gradient simple","conj gradient","Lagrange interp."],
1507 defaut = "gradient simple",
1508 fr = """ 0 : plan d''experience 1 : gradient simple 2 : gradient conj. 3 :
1509 interp. de Lagrange""",
1510 ang = """ 0 : list of tests 1: gradient 2 : conj. gradient 3 : lagrange interp.""",
1512 # -----------------------------------
1513 TOLERANCES_FOR_IDENTIFICATION = SIMP(statut ='o',
1514 # -----------------------------------
1515 typ = 'R', min= 4, max= 4,
1516 defaut = [1.E-3,1.E-3,1.E-3,1.E-4],
1517 fr = """ 4 nombres : precision absolue sur H, U, V, et precision relative sur
1518 la fonction cout""",
1519 ang = """ 4 numbers: absolute precision on H, U V, and relative precision on the
1522 # -----------------------------------
1523 MAXIMUM_NUMBER_OF_ITERATIONS_FOR_IDENTIFICATION = SIMP(statut ='o',
1524 # -----------------------------------
1527 fr = """ chaque iteration comprend au moins un calcul direct et un calcul
1529 ang = """ every iteration implies at least a direct and an adjoint computation""",
1532 # -----------------------------------
1533 SOURCES = FACT(statut='f',
1534 # -----------------------------------
1535 # -----------------------------------
1536 ABSCISSAE_OF_SOURCES = SIMP(statut ='o',
1537 # -----------------------------------
1538 typ = 'R', min=0, max='**',
1539 fr = """ Valeurs des abscisses des sources de debit et de traceur.""",
1540 ang = """ abscissae of sources of flowrate and/or tracer""",
1542 # -----------------------------------
1543 ORDINATES_OF_SOURCES = SIMP(statut ='o',
1544 # -----------------------------------
1545 typ = 'R', min=0, max='**',
1546 fr = """ Valeurs des ordonnees des sources de debit et de traceur.""",
1547 ang = """ ordinates of sources of flowrate and/or tracer""",
1549 # -----------------------------------
1550 WATER_DISCHARGE_OF_SOURCES = SIMP(statut ='o',
1551 # -----------------------------------
1552 typ = 'R', min=0, max='**',
1553 fr = """ Valeurs des debits des sources.""",
1554 ang = """ values of water discharge of sources""",
1556 # -----------------------------------
1557 VELOCITIES_OF_THE_SOURCES_ALONG_X = SIMP(statut ='f',
1558 # -----------------------------------
1559 typ = 'R', min=0, max='**',
1560 fr = """ Vitesses du courant a chacune des sources. Si elles ne sont pas
1561 donnees, on considere que la vitesse est celle du courant""",
1562 ang = """ Velocities at the sources. If they are not given, the velocity of the
1563 flow at this location is taken""",
1565 # -----------------------------------
1566 VELOCITIES_OF_THE_SOURCES_ALONG_Y = SIMP(statut ='f',
1567 # -----------------------------------
1568 typ = 'R', min=0, max='**',
1569 fr = """ Vitesses du courant a chacune des sources""",
1570 ang = """ Velocities at the sources""",
1572 # -----------------------------------
1573 TYPE_OF_SOURCES = SIMP(statut ='o',
1574 # -----------------------------------
1576 into = ["Normal","Dirac"],
1578 fr = """ 1: Source portee par une base elements finis 2: Source portee par une
1579 fonction de Dirac""",
1580 ang = """ 1: Source term multiplied by a finite element basis 2: Source term
1581 multiplied by a Dirac function""",
1583 # -----------------------------------
1584 SOURCES_FILE = SIMP(statut ='o',
1585 # -----------------------------------
1586 typ = ('Fichier','All Files (*)'),
1588 fr = """ Nom du fichier contenant les informations variables en temps des
1590 ang = """ Name of the file containing time-dependent information on sources""",
1593 # -----------------------------------
1594 WATER_QUALITY_INFO = FACT(statut='f',
1595 # -----------------------------------
1596 # -----------------------------------
1597 WATER_QUALITY_PROCESS = SIMP(statut ='f',
1598 # -----------------------------------
1601 fr = """ donne le numero du processus waq (1 ou 2 ou 3 ou 4 ou 5) 0- RIEN,
1602 1-O2, 2-BIOMASS, 3-EUTRO 4-MICROPOL 5-THERMIC)""",
1603 ang = """ gives the waq process number (from 1 to 5) 0-NOTHING, 1-O2, 2-BIOMASS,
1604 3-EUTRO 4-MICROPOL 5-THERMIC)""",
1607 # -----------------------------------
1608 ADVANCED_PHY = FACT(statut='f',
1609 # -----------------------------------
1610 # -----------------------------------
1611 WATER_DENSITY = SIMP(statut ='o',
1612 # -----------------------------------
1615 fr = """ Fixe la valeur de la masse volumique de l''eau.""",
1616 ang = """ set the value of water density""",
1618 # -----------------------------------
1619 GRAVITY_ACCELERATION = SIMP(statut ='o',
1620 # -----------------------------------
1623 fr = """ Fixe la valeur de l''acceleration de la pesanteur.""",
1624 ang = """ Set the value of the acceleration due to gravity.""",
1626 # -----------------------------------
1627 VERTICAL_STRUCTURES = SIMP(statut ='o',
1628 # -----------------------------------
1631 fr = """ Prise en compte de la force de trainee de structures verticales (il
1632 faut alors remplir la subroutine DRAGFO)""",
1633 ang = """ drag forces from vertical structures are taken into account.
1634 (subroutine DRAGFO must then be implemented)""",
1636 # -----------------------------------
1637 b_VERTICAL_STRUCTURESG = BLOC(condition="VERTICAL_STRUCTURES == True",
1638 # -----------------------------------
1639 # -----------------------------------
1640 Consigne = SIMP(statut ="o", homo="information", typ="TXM",
1641 # -----------------------------------
1642 defaut = "Fill the subroutine DRAGFO"),
1646 # -----------------------------------
1647 NUMERICAL_PARAMETERS_HYDRO = FACT(statut='o',
1648 # -----------------------------------
1649 # -----------------------------------
1650 EQUATIONS = SIMP(statut ='o',
1651 # -----------------------------------
1653 into = ['SAINT-VENANT FE','SAINT-VENANT FV','BOUSSINESQ'],
1654 defaut = 'SAINT-VENANT FE',
1655 fr = """ CHOIX DES EQUATIONS A RESOUDRE : SAINT-VENANT ELEMENTS FINIS,
1656 SAINT-VENANT VOLUMES FINIS OU BOUSSINESQ 20 CARACTERES""",
1657 ang = """ CHOICE OF EQUATIONS TO SOLVE : SAINT-VENANT FINITE ELEMENTS,
1658 SAINT-VENANT FINITE VOLUMES OR BOUSSINESQ 20 CHARACTERS""",
1660 # -----------------------------------
1661 b_EQUATIONSG = BLOC(condition="EQUATIONS == 'SAINT-VENANT FV'",
1662 # -----------------------------------
1663 # -----------------------------------
1664 FINITE_VOLUME_SCHEME = SIMP(statut ='o',
1665 # -----------------------------------
1667 into = ["Roe scheme","kinetic order 1","kinetic order 2","Zokagoa scheme order 1","Tchamen scheme order 1","HLLC scheme order 1","WAF scheme order 2"],
1668 defaut = "kinetic order 1",
1669 fr = """ 0 : schema de Roe 1 : cinetique ordre 1 2 : cinetique ordre 2 3 :
1670 schema de Zokagoa 4 : schema de Tchamen 5 : HLLC ordre 1 6 : WAF ordre
1672 ang = """ 0: Roe scheme 1: kinetic order 1 2: kinetic order 2 3 : Zokagoa scheme
1673 4 : Tchamen scheme 5 : HLLC order 1 6 : WAF order 2""",
1676 # -----------------------------------
1677 TREATMENT_OF_THE_LINEAR_SYSTEM = SIMP(statut ='o',
1678 # -----------------------------------
1680 into = ["coupled","Wave equation"],
1682 fr = """ 1 : Traitement couple 2 : equation d onde""",
1683 ang = """ 1 : Coupled 2 : wave equation""",
1686 # -----------------------------------
1687 FLUID = FACT(statut='f',
1688 # -----------------------------------
1689 # -----------------------------------
1690 CORIOLIS_EFFECT = FACT(statut='f',
1691 # -----------------------------------
1692 # -----------------------------------
1693 CORIOLIS = SIMP(statut ='o',
1694 # -----------------------------------
1697 fr = """ Prise en compte ou non de la force de Coriolis.""",
1698 ang = """ The Coriolis force is taken into account or ignored.""",
1700 # -----------------------------------
1701 CORIOLIS_COEFFICIENT = SIMP(statut ='o',
1702 # -----------------------------------
1705 fr = """ Fixe la valeur du coefficient de la force de Coriolis. Celui-ci doit
1706 etre calcule en fonction de la latitude l par la formule FCOR = 2w
1707 sin(l) , w etant la vitesse de rotation de la terre. w = 7.2921 10-5
1708 rad/s Les composantes de la force de Coriolis sont alors : FU = FCOR x V
1710 ang = """ Sets the value of the Coriolis force coefficient, in cartesian
1711 coordinates. This coefficient, denoted FCOR in the code, should be equal
1712 to 2 w sin(l)d where w denotes the earth angular speed of rotation and l
1713 the latitude. w = 7.27 10-5 rad/sec The Coriolis force components are
1714 then: FU = FCOR x V, FV = -FCOR x U In spherical coordinates, the
1715 latitudes are known""",
1718 # -----------------------------------
1719 TSUNAMI = FACT(statut='f',
1720 # -----------------------------------
1721 # -----------------------------------
1722 OPTION_FOR_TSUNAMI_GENERATION = SIMP(statut ='o',
1723 # -----------------------------------
1725 into = ["No Tsunami","Tsunami generated on the basis of the Okada model 1992"],
1726 defaut = "No Tsunami",
1730 # -----------------------------------
1731 PHYSICAL_CHARACTERISTICS_OF_THE_TSUNAMI = SIMP(statut ='o',
1732 # -----------------------------------
1733 typ = 'R', min=10, max=10,
1734 defaut = [100.,210000.,75000.,13.6,81.,41.,110.,0.,0.,3.],
1739 # -----------------------------------
1740 SECONDARY_CURRENTS_INFO = FACT(statut='f',
1741 # -----------------------------------
1742 # -----------------------------------
1743 SECONDARY_CURRENTS = SIMP(statut ='o',
1744 # -----------------------------------
1747 fr = """ Pour prendre en compte les courants secondaires""",
1748 ang = """ Using the parametrisation for secondary currents""",
1750 # -----------------------------------
1751 b_SECONDARY_CURRENTSG = BLOC(condition="SECONDARY_CURRENTS == True",
1752 # -----------------------------------
1753 # -----------------------------------
1754 PRODUCTION_COEFFICIENT_FOR_SECONDARY_CURRENTS = SIMP(statut ='o',
1755 # -----------------------------------
1758 fr = """ Une constante dans les termes de creation de Omega""",
1759 ang = """ A constant in the production terms of Omega""",
1761 # -----------------------------------
1762 DISSIPATION_COEFFICIENT_FOR_SECONDARY_CURRENTS = SIMP(statut ='o',
1763 # -----------------------------------
1766 fr = """ Coefficient de dissipation de Omega""",
1767 ang = """ Coefficient of dissipation term of Omega""",
1773 # -----------------------------------------------------------------------
1774 GENERAL_PARAMETERS = PROC(nom= "GENERAL_PARAMETERS",op = None,
1775 # -----------------------------------------------------------------------
1776 UIinfo = {"groupes": ("CACHE")},
1777 # -----------------------------------
1778 DEBUGGER = SIMP(statut ='o',
1779 # -----------------------------------
1782 fr = """ Pour imprimer la sequence des appels, mettre 1""",
1783 ang = """ If 1, calls of subroutines will be printed in the listing""",
1785 # -----------------------------------
1786 TIME = FACT(statut='o',
1787 # -----------------------------------
1788 # -----------------------------------
1789 TIME_STEP = SIMP(statut ='o',
1790 # -----------------------------------
1793 fr = """ Definit le pas de temps en secondes. Remarque : Pour une bonne
1794 precision; il est souhaitable de choisir le pas de temps de telle sorte
1795 que le nombre de Courant de propagation soit inferieur a 2 ; voir 3.
1796 Ceci peut etre realisable en hydraulique fluviale ; mais ne l''est
1797 pratiquement jamais en hydraulique maritime ou l''on peut atteindre des
1799 ang = """ Specifies the time step in seconds.""",
1801 # -----------------------------------
1802 NUMBER_OF_TIME_STEPS = SIMP(statut ='f',
1803 # -----------------------------------
1806 fr = """ Definit le nombre de pas de temps effectues lors de l''execution du
1808 ang = """ Specifies the number of time steps performed when running the code.""",
1810 # -----------------------------------
1811 DURATION = SIMP(statut ='f',
1812 # -----------------------------------
1815 fr = """ duree de la simulation. alternative au parametre nombre de pas de
1816 temps. On en deduit le nombre de pas de temps en prenant l''entier le
1817 plus proche de (duree du calcul/pas de temps). Si le nombre de pas de
1818 temps est aussi donne, on prend la plus grande valeur""",
1819 ang = """ duration of simulation. May be used instead of the parameter NUMBER OF
1820 TIME STEPS. The nearest integer to (duration/time step) is taken. If
1821 NUMBER OF TIME STEPS is also given, the greater value is taken""",
1823 # -----------------------------------
1824 ORIGINAL_DATE_OF_TIME = SIMP(statut ='o',
1825 # -----------------------------------
1826 typ = 'I', min= 3, max= 3,
1827 defaut = [1900,1,1],
1828 fr = """ Permet de fixer la date d''origine des temps du modele lors de la
1829 prise en compte de la force generatrice de la maree.""",
1830 ang = """ Give the date of the time origin of the model when taking into account
1831 the tide generating force.""",
1833 # -----------------------------------
1834 ORIGINAL_HOUR_OF_TIME = SIMP(statut ='o',
1835 # -----------------------------------
1836 typ = 'I', min= 3, max= 3,
1838 fr = """ Permet de fixer l''heure d''origine des temps du modele lors de la
1839 prise en compte de la force generatrice de la maree.""",
1840 ang = """ Give the time of the time origin of the model when taking into account
1841 of the tide generator force.""",
1843 # -----------------------------------
1844 STOP_IF_A_STEADY_STATE_IS_REACHED = SIMP(statut ='o',
1845 # -----------------------------------
1848 fr = """ A UTILISER AVEC LE MOT-CLE : CRITERES D''ARRET""",
1849 ang = """ TO BE USED WITH THE KEY-WORD: STOP CRITERIA""",
1851 # -----------------------------------
1852 b_STOP_IF_A_STEADY_STATE_IS_REACHEDG = BLOC(condition="STOP_IF_A_STEADY_STATE_IS_REACHED == True",
1853 # -----------------------------------
1854 # -----------------------------------
1855 STOP_CRITERIA = SIMP(statut ='o',
1856 # -----------------------------------
1857 typ = 'R', min= 3, max= 3,
1858 defaut = [1.E-4,1.E-4,1.E-4],
1859 fr = """ Criteres d''arret pour un ecoulement permanent ces coefficients sont
1860 respectivement appliques a 1) U et V 2) H 3) T A utiliser avec le
1861 mot-cle : ARRET SI UN ETAT PERMANENT EST ATTEINT""",
1862 ang = """ Stop criteria for a steady state These coefficients are applied
1863 respectively to 1) U and V 2) H 3) T To be used with the key-word: STOP
1864 IF A STEADY STATE IS REACHED""",
1867 # -----------------------------------
1868 CONTROL_OF_LIMITS = SIMP(statut ='o',
1869 # -----------------------------------
1872 fr = """ Utiliser avec le mot-cle : valeurs limites, le programme s''arrete si
1873 les limites sur u,v,h ou t sont depassees""",
1874 ang = """ Use with the key-word : limit values, the program is stopped if the
1875 limits on u,v,h, or t are trespassed""",
1877 # -----------------------------------
1878 b_CONTROL_OF_LIMITSG = BLOC(condition="CONTROL_OF_LIMITS == True",
1879 # -----------------------------------
1880 # -----------------------------------
1881 LIMIT_VALUES = SIMP(statut ='o',
1882 # -----------------------------------
1883 typ = 'R', min= 8, max= 8,
1884 defaut = [-1000.,9000.,-1000.,1000.,-1000.,1000.,-1000.,1000.],
1885 fr = """ Utilise avec le mot-cle CONTROLE DES LIMITES valeurs mini et maxi
1886 acceptables pour H,U,V et T dans l''ordre suivant : min(H) max(H) min(U)
1887 max(U) min(V) max(V) min(T) max(T)""",
1888 ang = """ To be used with the key-word CONTROL OF LIMITS min and max acceptable
1889 values for H,U,V et T in the following order : min(H) max(H) min(U)
1890 max(U) min(V) max(V) min(T) max(T)""",
1893 # -----------------------------------
1894 VARIABLE_TIME_STEP = SIMP(statut ='o',
1895 # -----------------------------------
1898 fr = """ Pas de temps variable pour avoir un nombre de courant souhaite""",
1899 ang = """ Variable time-step to get a given Courant number""",
1901 # -----------------------------------
1902 b_VARIABLE_TIME_STEPG = BLOC(condition="VARIABLE_TIME_STEP == True",
1903 # -----------------------------------
1904 # -----------------------------------
1905 DESIRED_COURANT_NUMBER = SIMP(statut ='o',
1906 # -----------------------------------
1909 fr = """ Nombre de Courant souhaite en cas de pas de temps variable""",
1910 ang = """ Desired Courant number when VARIABLE TIME-STEP is set to YES""",
1914 # -----------------------------------
1915 LOCATION = FACT(statut='o',
1916 # -----------------------------------
1917 # -----------------------------------
1918 ORIGIN_COORDINATES = SIMP(statut ='o',
1919 # -----------------------------------
1920 typ = 'I', min= 2, max= 2,
1922 fr = """ Valeur en metres, utilise pour eviter les trops grands nombres,
1923 transmis dans le format Selafin mais pas d''autre traitement pour
1925 ang = """ Value in metres, used to avoid large real numbers, added in Selafin
1926 format, but so far no other treatment""",
1928 # -----------------------------------
1929 SPHERICAL_COORDINATES = SIMP(statut ='o',
1930 # -----------------------------------
1933 fr = """ Choix des coordonnees spheriques pour la realisation du calcul ( pour
1934 les grands domaines de calcul). Attention : cette option est etroitement
1935 liee au maillage qui doit avoir ete saisi sur une carte marine en
1936 projection de Mercator. Il faut de plus relever sur la carte la LATITUDE
1937 DU POINT ORIGINE (autre mot-cle) qui correspond dans le maillage a
1938 l''ordonnee y = 0.""",
1939 ang = """ Selection of spherical coordinates to perform the computation (for
1940 large computation domains). Warning: this option is closely related to
1941 the mesh that should have been entered onto a nautical chart drawn as
1942 per Mercator projection The LATITUDE OF ORIGIN POINT (another keyword),
1943 which corresponds to ordinate y=0 in the mesh, must moreover be given.""",
1945 # -----------------------------------
1946 b_SPHERICAL_COORDINATESG = BLOC(condition="SPHERICAL_COORDINATES == True",
1947 # -----------------------------------
1948 # -----------------------------------
1949 LATITUDE_OF_ORIGIN_POINT = SIMP(statut ='o',
1950 # -----------------------------------
1953 fr = """ Determine l''origine utilisee pour le calcul de latitudes lorsque
1954 l''on effectue un calcul en coordonnees spheriques.""",
1955 ang = """ Determines the origin used for computing latitudes when a computation
1956 is made in spherical coordinates. this latitude is in particular used to
1957 compute the Coriolis force. In cartesian coordinates, Coriolis
1958 coefficient is considered constant.""",
1961 # -----------------------------------
1962 LONGITUDE_OF_ORIGIN_POINT = SIMP(statut ='o',
1963 # -----------------------------------
1966 fr = """ Fixe la valeur de la longitude du point origine du modele, lors de
1967 l''utilisation de la force generatrice de la maree.""",
1968 ang = """ Give the value of the longitude of the origin point of the model, when
1969 taking into account of the tide generator force.""",
1971 # -----------------------------------
1972 NORTH = SIMP(statut ='f',
1973 # -----------------------------------
1976 fr = """ Direction du nord en degres, par rapport a l''axe des y dans le sens
1977 trigonometrique. Notation decimale 10.5 signifie 10 degres et trente
1979 ang = """ Angle of the North with the y axis, in degrees. 10.5 means 10 degrees
1982 # -----------------------------------
1983 SPATIAL_PROJECTION_TYPE = SIMP(statut ='o',
1984 # -----------------------------------
1986 into = ["CARTESIAN, NOT GEOREFERENCED","MERCATOR","LATITUDE LONGITUDE"],
1987 defaut = "CARTESIAN, NOT GEOREFERENCED",
1988 fr = """ Option 2 ou 3 obligatoire pour les coordonnees spheriques Option 3 :
1989 latitude et longitude en degres !""",
1990 ang = """ Option 2 or 3 mandatory for spherical coordinates Option 3: latitude
1991 and longitude in degrees!""",
1995 # -----------------------------------------------------------------------
1996 NUMERICAL_PARAMETERS = PROC(nom= "NUMERICAL_PARAMETERS",op = None,
1997 # -----------------------------------------------------------------------
1998 UIinfo = {"groupes": ("CACHE")},
1999 # -----------------------------------
2000 SOLVER_INFO = FACT(statut='o',
2001 # -----------------------------------
2002 # -----------------------------------
2003 SOLVER = SIMP(statut ='o',
2004 # -----------------------------------
2006 into = ["conjugate gradient on a normal equation","conjugate gradient","conjugate residual","minimum error","cgstab","gmres","direct"],
2007 defaut = "conjugate gradient on a normal equation",
2008 fr = """ Permet de choisir le solveur utilise pour la resolution de l''etape de
2009 propagation. Toutes les methodes proposees actuellement s''apparentent
2010 au Gradient Conjugue. Ce sont : 1 : gradient conjugue 2 : residu
2011 conjugue 3 : gradient conjugue sur equation normale 4 : erreur minimale
2012 5 : gradient conjugue carre (non programme) 6 : gradient conjugue carre
2013 stabilise (cgstab) 7 : gmres (voir aussi option du solveur) 8 : direct""",
2014 ang = """ Makes it possible to select the solver used for solving the
2015 propagation step. All the currently available methods are variations of
2016 the Conjugate Gradient method. They are as follows: 1: conjugate
2017 gradient 2: conjugate residual 3: conjugate gradient on a normal
2018 equation 4: minimum error 5: conjugate gradient squared (not
2019 implemented) 6: conjugate gradient squared stabilised (cgstab) 7: gmres
2020 (see option for solver) 8: direct""",
2022 # -----------------------------------
2023 b_SOLVERG = BLOC(condition="SOLVER == 'gmres'",
2024 # -----------------------------------
2025 # -----------------------------------
2026 SOLVER_OPTION = SIMP(statut ='o',
2027 # -----------------------------------
2030 fr = """ si le solveur est GMRES (7) le mot cle est la dimension de l''espace
2031 de KRYLOV (valeurs conseillees entre 2 et 15)""",
2032 ang = """ WHEN GMRES (7) IS CHOSEN, DIMENSION OF THE KRYLOV SPACE TRY VALUES
2033 BETWEEN 2 AND 15""",
2036 # -----------------------------------
2037 SOLVER_ACCURACY = SIMP(statut ='o',
2038 # -----------------------------------
2041 fr = """ Precision demandee pour la resolution de l''etape de propagation (cf.
2042 Note de principe).""",
2043 ang = """ Required accuracy for solving the propagation step (refer to Principle
2046 # -----------------------------------
2047 MAXIMUM_NUMBER_OF_ITERATIONS_FOR_SOLVER = SIMP(statut ='o',
2048 # -----------------------------------
2051 fr = """ Les algorithmes utilises pour la resolution de l''etape de propagation
2052 etant iteratifs; il est necessaire de limiter le nombre d''iterations
2053 autorisees. Remarque : un maximum de 40 iterations par pas de temps
2054 semble raisonnable.""",
2055 ang = """ Since the algorithms used for solving the propagation step are
2056 iterative, the allowed number of iterations should be limited. NOTE: a
2057 maximum number of 40 iterations per time step seems to be reasonable.""",
2059 # -----------------------------------
2060 CONTINUITY_CORRECTION = SIMP(statut ='o',
2061 # -----------------------------------
2064 fr = """ Corrige les vitesses sur les points avec hauteur imposee ou
2065 l''equation de continuite n''a pas ete resolue""",
2066 ang = """ Correction of the velocities on points with a prescribed elevation,
2067 where the continuity equation has not been solved""",
2069 # -----------------------------------
2070 PRECONDITIONING = SIMP(statut ='o',
2071 # -----------------------------------
2073 into = ["diagonal","no preconditioning","block-diagonal (4-9 matrices)","absolute value of diagonal","crout","gauss-seidel","diagonal and crout"],
2074 defaut = "diagonal",
2075 fr = """ Permet de preconditionner le systeme de l''etape de propagation afin
2076 d''accelerer la convergence lors de sa resolution. - 0 : pas de
2077 preconditionnement; - 2 : preconditionnement diagonal. - 3 :
2078 preconditionnement diagonal-bloc - 7 : preconditionnement de Crout par
2079 element ou segment -11 : preconditionnement de Gauss-Seidel par element
2080 ou segment Certains preconditionnements sont cumulables (les diagonaux 2
2081 ou 3 avec les autres) Pour cette raison on ne retient que les nombres
2082 premiers pour designer les preconditionnements. Si l''on souhaite en
2083 cumuler plusieurs on formera le produit des options correspondantes.""",
2084 ang = """ Choice of the preconditioning in the propagation step linear system
2085 that the convergence is speeded up when it is being solved. 0: no
2086 preconditioning 2: diagonal preconditioning 3: block-diagonal
2087 preconditioning (systemes a 4 ou 9 matrices) 7: Crout''s preconditioning
2088 per element or segment 11: Gauss-Seidel''s preconditioning per element
2089 or segment Some operations (either 2 or 3 diagonal preconditioning) can
2090 be performed concurrently with the others. Only prime numbers are
2091 therefore kept to denote the preconditioning operations. When several of
2092 them are to be performed concurrently, the product of relevant options
2095 # -----------------------------------
2096 C_U_PRECONDITIONING = SIMP(statut ='o',
2097 # -----------------------------------
2100 fr = """ Changement de variable de H en C dans le systeme lineaire final""",
2101 ang = """ Change of variable from H to C in the final linear system""",
2104 # -----------------------------------
2105 DISCRETISATIONS_IMPLICITATION = FACT(statut='o',
2106 # -----------------------------------
2107 # -----------------------------------
2108 IMPLICITATION_FOR_DEPTH = SIMP(statut ='o',
2109 # -----------------------------------
2112 fr = """ Fixe la valeur du coefficient d''implicitation sur C dans l''etape de
2113 propagation (cf. Note de principe). Les valeurs inferieures a 0.5
2114 donnent un schema instable.""",
2115 ang = """ Sets the value of the implicitation coefficient for C (the celerity of
2116 waves) in the propagation step (refer to principle note). Values below
2117 0.5 result in an unstable scheme.""",
2119 # -----------------------------------
2120 IMPLICITATION_FOR_VELOCITY = SIMP(statut ='o',
2121 # -----------------------------------
2124 fr = """ Fixe la valeur du coefficient d''implicitation sur la vitesse dans
2125 l''etape de propagation (cf. Note de principe). Les valeurs inferieures
2126 a 0.5 donnent un schema instable.""",
2127 ang = """ Sets the value of the implicitation coefficient for velocity in the
2128 propagation step (refer to principle note). Values below 0.5 result in
2129 an unstable condition.""",
2131 # -----------------------------------
2132 DISCRETIZATIONS_IN_SPACE = SIMP(statut ='f',
2133 # -----------------------------------
2134 typ = 'TXM', max='**',
2135 into = ["linear","quasi-bubble","quadratic"],
2136 defaut = ["linear","linear","linear","linear"],
2137 fr = """ Choix de la discretisation pour chaque variable ces coefficients sont
2138 respectivement appliques a 1) U et V 2) H 3) T 4) K ET EPSILON (NON
2139 PROGRAMME) 11 : lineaire 12 : quasi-bulle 13 : quadratique""",
2140 ang = """ Choice of space discretisation for every variable These coefficients
2141 are applied respectively to 1) U and V 2) H 3) T 4) K and EPSILON (NOT
2142 IMPLEMENTED) 11: linear 12: quasi-bubble 13: quadratic""",
2144 # -----------------------------------
2145 b_DISCRETIZATIONS_IN_SPACEG = BLOC(condition="DISCRETIZATIONS_IN_SPACE != None",
2146 # -----------------------------------
2147 # -----------------------------------
2148 Consigne = SIMP(statut ="o", homo="information", typ="TXM",
2149 # -----------------------------------
2150 defaut = "Choice of space discretisation for every variable These coefficients are applied respectively to 1) U and V 2) H 3) T 4) K and EPSILON"),
2153 # -----------------------------------
2154 PROPAGATION_INFO = FACT(statut='o',
2155 # -----------------------------------
2156 # -----------------------------------
2157 PROPAGATION = SIMP(statut ='o',
2158 # -----------------------------------
2161 fr = """ Prise en compte ou non de la propagation de la vitesse et de la
2162 hauteur d''eau. La diffusion etant contenue dans cette etape sera
2163 supprimee aussi.""",
2164 ang = """ Determines whether the propagation step is taken into account or not.
2165 The diffusion being included in that step will be deleted as well.""",
2167 # -----------------------------------
2168 b_PROPAGATIONG = BLOC(condition="PROPAGATION == True",
2169 # -----------------------------------
2170 # -----------------------------------
2171 MEAN_DEPTH_FOR_LINEARIZATION = SIMP(statut ='o',
2172 # -----------------------------------
2175 fr = """ Fixe la hauteur d''eau autour de laquelle s''effectue la linearisation
2176 lorsque l''option PROPAGATION LINEARISEE est choisie.""",
2177 ang = """ Sets the water depth about which the linearization is made when the
2178 LINEARIZED PROPAGATION OPTION is selected.""",
2180 # -----------------------------------
2181 INITIAL_GUESS_FOR_U = SIMP(statut ='o',
2182 # -----------------------------------
2184 into = ["zero","previous","extrapolation"],
2185 defaut = "previous",
2186 fr = """ Tir initial du solveur de l''etape de propagation. Offre la
2187 possibilite de modifier la valeur initiale de U, a chaque iteration,
2188 dans l''etape de propagation en utilisant les valeurs finales de cette
2189 variable aux pas de temps precedents. Ceci peut permettre d''accelerer
2190 la vitesse de convergence lors de la resolution du systeme. Trois
2191 possibilites sont offertes : 0 : U = 0 1 : U = U(n) 2 : U = 2 U(n)-
2192 U(n-1) (extrapolation)""",
2193 ang = """ Initial guess for the solver in the propagation step. Makes it
2194 possible to modify the initial value of U, upon each iteration in the
2195 propagation step, by using the ultimate values this variable had in the
2196 earlier time steps. Thus, the convergence can be speeded up when the
2197 system is being solved. 3 options are available: 0 : U = 0 1 : U = U(n)
2198 2 : U = 2 U(n)- U(n-1) (extrapolation)""",
2201 # -----------------------------------
2202 INITIAL_GUESS_FOR_H = SIMP(statut ='o',
2203 # -----------------------------------
2205 into = ["previous","zero","extrapolation"],
2206 defaut = "previous",
2207 fr = """ Tir initial du solveur de l''etape de propagation. Offre la
2208 possibilite de modifier la valeur initiale de DH, accroissement de H, a
2209 chaque iteration, dans l''etape de propagation en utilisant les valeurs
2210 finales de cette variable aux pas de temps precedents. Ceci peut
2211 permettre d''accelerer la vitesse de convergence lors de la resolution
2212 du systeme. Trois possibilites sont offertes : 0 : DH = 0. 1 : DH = DHn
2213 (valeur finale de DH au pas de temps precedent), 2 : DH = 2DHn - DHn-1
2214 (extrapolation).""",
2215 ang = """ Initial guess for the solver in the propagation step. Makes it
2216 possible to modify the initial value of C, upon each iteration in the
2217 propagation step, by using the ultimate values this variable had in the
2218 earlier time steps. Thus, the convergence can be speeded up when the
2219 system is being solved. 3 options are available: 0: DH = 0 1: DH = DHn
2220 (ultimate DH value in the next previous time step) 2: DH = 2DHn - DHn-1
2223 # -----------------------------------
2224 LINEARIZED_PROPAGATION = SIMP(statut ='o',
2225 # -----------------------------------
2228 fr = """ Permet de lineariser l''etape de propagation; par exemple lors de la
2229 realisation de cas tests pour lesquels on dispose d''une solution
2230 analytique dans le cas linearise.""",
2231 ang = """ Provided for linearizing the propagation step, e.g. when performing
2232 test-cases for which an analytical solution in the linearized case is
2236 # -----------------------------------
2237 ADVECTION_INFO = FACT(statut='o',
2238 # -----------------------------------
2239 # -----------------------------------
2240 ADVECTION = SIMP(statut ='o',
2241 # -----------------------------------
2244 fr = """ Prise en compte ou non des termes de convection. En cas de reponse
2245 positive; on peut encore supprimer certains termes de convection avec
2246 les mots-cles CONVECTION DE ...""",
2247 ang = """ Are the advection terms taken into account or not? If YES, some
2248 advection terms can still be deleted using the keywords -ADVECTION OF
2251 # -----------------------------------
2252 ADVECTION_OF_H = SIMP(statut ='o',
2253 # -----------------------------------
2256 fr = """ Prise en compte ou non de la convection de H. Il s''agit en fait dans
2257 la version 2.0 de la convection de C""",
2258 ang = """ The advection of H is taken into account or ignored. Actually, in
2259 version 2.0, the matter is about C advection.""",
2261 # -----------------------------------
2262 ADVECTION_OF_U_AND_V = SIMP(statut ='f',
2263 # -----------------------------------
2266 fr = """ Prise en compte ou non de la convection de U et V.""",
2267 ang = """ The advection of U and V is taken into account or ignored.""",
2269 # -----------------------------------
2270 b_ADVECTION_OF_U_AND_VG = BLOC(condition="ADVECTION_OF_U_AND_V == True",
2271 # -----------------------------------
2272 # -----------------------------------
2273 SCHEME_FOR_ADVECTION_OF_VELOCITIES = SIMP(statut ='o',
2274 # -----------------------------------
2276 into = ["NO ADVECTION","CHARACTERISTICS","EXPLICIT + SUPG","EXPLICIT LEO POSTMA","EXPLICIT + MURD SCHEME N","EXPLICIT + MURD SCHEME PSI","N-SCHEME FOR TIDAL FLATS","N-SCHEME FOR TIDAL FLATS","ERIA SCHEME"],
2277 defaut = "CHARACTERISTICS",
2278 fr = """ Choix du schema de convection pour les vitesses, remplace FORME DE LA
2280 ang = """ Choice of the advection scheme for the velocities, replaces TYPE OF
2284 # -----------------------------------
2285 TYPE_OF_ADVECTION = SIMP(statut ='f',
2286 # -----------------------------------
2287 typ = 'TXM', max='**',
2288 into = ["CHARACTERISTICS","SUPG","CONSERVATIVE N-SCHEME","CONSERVATIVE N-SCHEME","CONSERVATIVE PSI-SCHEME","EDGE-BASED N-SCHEME","EDGE-BASED N-SCHEME","ERIA SCHEME"],
2289 defaut = ["CHARACTERISTICS","CONSERVATIVE PSI-SCHEME","CHARACTERISTICS","CHARACTERISTICS"],
2290 fr = """ Choix du schema de convection pour chaque variable ces coefficients
2291 sont respectivement appliques a 1) U et V 2) H 3) T 4) K ET EPSILON 1 :
2292 caracteristiques sur h 2 : SUPG 3 : Schema N conservatif 4 : Schema N
2293 conservatif 5 : Schema PSI conservatif 6 : Schema PSI non conservatif 7
2294 : schema N implicite non conservatif 13 : Schema N par segment 14 :
2295 Schema N par segment Second integer must be 5""",
2296 ang = """ Choice of advection schemes for every variable These coefficients are
2297 applied respectively to 1) U et V 2) H 3) T 4) K and EPSILON 1:
2298 characteristics 2: SUPG 3: Conservative N-scheme 4: Conservative
2299 N-scheme 5: Conservative PSI-scheme 6 : Non conservative PSI scheme 7 :
2300 Implicit non conservative N scheme 13 : Edge-based N-scheme 14 :
2301 Edge-based N-scheme Second integer must be 5""",
2303 # -----------------------------------
2304 b_TYPE_OF_ADVECTIONG = BLOC(condition="TYPE_OF_ADVECTION != None",
2305 # -----------------------------------
2306 # -----------------------------------
2307 Consigne = SIMP(statut ="o", homo="information", typ="TXM",
2308 # -----------------------------------
2309 defaut = "Choice of space discretisation for every variable These coefficients are applied respectively to 1) U and V 2) H 3) T 4) K and EPSILON"),
2311 # -----------------------------------
2312 OPTION_FOR_CHARACTERISTICS = SIMP(statut ='o',
2313 # -----------------------------------
2315 into = ["strong","weak"],
2317 fr = """ 1: forme forte 2: forme faible""",
2318 ang = """ 1: strong form 2: weak form""",
2320 # -----------------------------------
2321 SUPG_OPTION = SIMP(statut ='o',
2322 # -----------------------------------
2323 typ = 'I', min=0, max='**',
2325 fr = """ 0:pas de decentrement SUPG
2328 ces coefficients sont respectivement appliques a 1) U et V 2) H 3) T 4)
2330 ang = """ 0:no upwinding 1: classical SUPG 2:modified SUPG These coefficients
2331 are applied respectively to 1) U et V 2) H 3) T 4) K and EPSILON""",
2333 # -----------------------------------
2334 NUMBER_OF_GAUSS_POINTS_FOR_WEAK_CHARACTERISTICS = SIMP(statut ='f',
2335 # -----------------------------------
2338 fr = """ Voir les release notes 6.3""",
2339 ang = """ See release notes 6.3""",
2341 # -----------------------------------
2342 MASS_LUMPING_FOR_WEAK_CHARACTERISTICS = SIMP(statut ='o',
2343 # -----------------------------------
2346 fr = """ Applique a la matrice de masse""",
2347 ang = """ To be applied to the mass matrix""",
2349 # -----------------------------------
2350 b_MAXIMUM_NUMBER_OF_ITERATIONS_FOR_ADVECTION_SCHEMESF = BLOC(condition="(ADVECTION_OF_TRACERS == True and SCHEME_FOR_ADVECTION_OF_TRACERS == 'EDGE-BASED N-SCHEME') or (ADVECTION_OF_K_AND_EPSILON == True and SCHEME_FOR_ADVECTION_OF_K_EPSILON == 'EDGE-BASED N-SCHEME') or (ADVECTION_OF_U_AND_V == True and SCHEME_FOR_ADVECTION_OF_VELOCITIES == 'EDGE-BASED N-SCHEME')",
2351 # -----------------------------------
2353 # -----------------------------------
2354 MAXIMUM_NUMBER_OF_ITERATIONS_FOR_ADVECTION_SCHEMES = SIMP(statut ='o',
2355 # -----------------------------------
2358 fr = """ Seulement pour schemes 13 et 14""",
2359 ang = """ Only for schemes 13 and 14""",
2361 # -----------------------------------
2362 UPWIND_COEFFICIENTS = SIMP(statut ='o',
2363 # -----------------------------------
2364 typ = 'R', min= 4, max= 4,
2365 defaut = [1.,1.,1.,1],
2366 fr = """ Coefficients utilises par la methode S.U.P.G. ces coefficients sont
2367 respectivement appliques a 1) U et V 2) H ou C 3) T 4) K ET EPSILON""",
2368 ang = """ Upwind coefficients used by the S.U.P.G. method These coefficients are
2369 applied respectively to 1) U and V 2) H or C 3) T 4) K and epsilon""",
2371 # -----------------------------------
2372 MASS_LUMPING_ON_H = SIMP(statut ='o',
2373 # -----------------------------------
2376 fr = """ TELEMAC offre la possibilite d''effectuer du mass-lumping sur H ou U.
2377 Ceci revient a ramener tout ou partie (suivant la valeur de ce
2378 coefficient) des matrices AM1 (h) ou AM2 (U) et AM3 (V) sur leur
2379 diagonale. Cette technique permet d''accelerer le code dans des
2380 proportions tres importantes et de le rendre egalement beaucoup plus
2381 stable. Cependant les solutions obtenues se trouvent lissees. Ce
2382 parametre fixe le taux de mass-lumping effectue sur h.""",
2383 ang = """ TELEMAC provides an opportunity to carry out mass-lumping either on
2384 C,H or on the velocity. This is equivalent to bringing the matrices AM1
2385 (h) or AM2 (U) and AM3 (V) wholly or partly, back onto their diagonal.
2386 Thanks to that technique, the code can be speeded up to a quite
2387 significant extent and it can also be made much more stable. The
2388 resulting solutions, however, become artificially smoothed. This
2389 parameter sets the extent of mass-lumping that is performed on h.""",
2391 # -----------------------------------
2392 MASS_LUMPING_ON_VELOCITY = SIMP(statut ='o',
2393 # -----------------------------------
2396 fr = """ Fixe le taux de mass-lumping effectue sur la vitesse.""",
2397 ang = """ Sets the amount of mass-lumping that is performed on the velocity.""",
2399 # -----------------------------------
2400 SCHEME_OPTION_FOR_ADVECTION_OF_VELOCITIES = SIMP(statut ='f',
2401 # -----------------------------------
2404 fr = """ Si present remplace et a priorite sur : OPTION POUR LES
2405 CARACTERISTIQUES OPTION DE SUPG Si schema PSI ou N : 1=explicite
2406 2=predicteur-correcteur 3=predicteur-correcteur deuxieme ordre en temps
2408 ang = """ If present replaces and has priority over: OPTION FOR CHARACTERISTICS
2409 SUPG OPTION if N or PSI SCHEME: 1=explicit 2=predictor-corrector 3=
2410 predictor-corrector second-order in time 4= implicit""",
2412 # -----------------------------------
2413 FREE_SURFACE_GRADIENT_COMPATIBILITY = SIMP(statut ='o',
2414 # -----------------------------------
2417 fr = """ Des valeurs inferieures a 1 suppriment les oscillations parasites""",
2418 ang = """ Values less than 1 suppress spurious oscillations""",
2420 # -----------------------------------
2421 NUMBER_OF_SUB_ITERATIONS_FOR_NON_LINEARITIES = SIMP(statut ='o',
2422 # -----------------------------------
2425 fr = """ Permet de reactualiser, pour un meme pas de temps, les champs
2426 convecteur et propagateur au cours de plusieurs sous-iterations. A la
2427 premiere sous-iteration, ces champs sont donnes par C et le champ de
2428 vitesses au pas de temps precedent. Aux iterations suivantes, ils sont
2429 pris egaux au champ de vitesse obtenu a la fin de la sous-iteration
2430 precedente. Cette technique permet d''ameliorer la prise en compte des
2432 ang = """ Used for updating, within one time step, the advection and propagation
2433 field. upon the first sub-iteration, these fields are given by C and the
2434 velocity field in the previous time step. At subsequent iterations, the
2435 results of the previous sub-iteration is used to update the advection
2436 and propagation field. The non-linearities can be taken into account
2437 through this technique.""",
2439 # -----------------------------------
2440 b_TREATMENT_OF_FLUXES_AT_THE_BOUNDARIESF = BLOC(condition="(ADVECTION_OF_TRACERS == True and SCHEME_FOR_ADVECTION_OF_TRACERS in ['EDGE-BASED N-SCHEME','SUPG','CONSERVATIVE N-SCHEME','CONSERVATIVE PSI-SCHEME']) or (ADVECTION_OF_K_AND_EPSILON == True and SCHEME_FOR_ADVECTION_OF_K_EPSILON in ['EDGE-BASED N-SCHEME','SUPG','CONSERVATIVE N-SCHEME','CONSERVATIVE PSI-SCHEME']) or (ADVECTION_OF_U_AND_V == True and SCHEME_FOR_ADVECTION_OF_VELOCITIES in ['EDGE-BASED N-SCHEME','SUPG','CONSERVATIVE N-SCHEME','CONSERVATIVE PSI-SCHEME'])",
2441 # -----------------------------------
2443 # -----------------------------------
2444 TREATMENT_OF_FLUXES_AT_THE_BOUNDARIES = SIMP(statut ='o',
2445 # -----------------------------------
2447 into = ["Priority to prescribed values","Priority to fluxes"],
2448 defaut = "Priority to prescribed values",
2449 fr = """ Utilise pour les schemas SUPG, PSI et N, avec option 2, on ne retrouve
2450 pas exactement les valeurs imposees des traceurs, mais le flux est
2452 ang = """ Used so far only with the SUPG, PSI and N schemes. With option 2,
2453 Dirichlet prescribed values are not obeyed, but the fluxes are correct""",
2455 # -----------------------------------
2456 NUMBER_OF_CORRECTIONS_OF_DISTRIBUTIVE_SCHEMES = SIMP(statut ='f',
2457 # -----------------------------------
2460 fr = """ Pour les options avec predicteur-correcteur""",
2461 ang = """ For predictor-corrector options""",
2463 # -----------------------------------
2464 NUMBER_OF_SUB_STEPS_OF_DISTRIBUTIVE_SCHEMES = SIMP(statut ='f',
2465 # -----------------------------------
2468 fr = """ Pour les options predicteur-correcteur avec schema localement
2470 ang = """ Only for implicit scheme with predictor-corrector""",
2472 # -----------------------------------
2473 PSI_SCHEME_OPTION = SIMP(statut ='f',
2474 # -----------------------------------
2476 into = ["explicit","predictor-corrector"],
2477 defaut = "explicit",
2478 fr = """ 1: explicite 2: predicteur-correcteur""",
2479 ang = """ 1: explicit 2: predictor-corrector""",
2482 # -----------------------------------
2483 DIFFUSION = FACT(statut='o',
2484 # -----------------------------------
2485 # -----------------------------------
2486 DIFFUSION_OF_VELOCITY = SIMP(statut ='o',
2487 # -----------------------------------
2490 fr = """ Permet de decider si l''on prend ou non en compte la diffusion des
2492 ang = """ Makes it possible to decide whether the diffusion of velocity (i.e.
2493 viscosity) is taken into account or not.""",
2495 # -----------------------------------
2496 b_DIFFUSION_OF_VELOCITYG = BLOC(condition="DIFFUSION_OF_VELOCITY == True",
2497 # -----------------------------------
2498 # -----------------------------------
2499 IMPLICITATION_FOR_DIFFUSION_OF_VELOCITY = SIMP(statut ='o',
2500 # -----------------------------------
2503 fr = """ Fixe la valeur du coefficient d''implicitation sur les termes de
2504 diffusion des vitesses""",
2505 ang = """ Sets the value of the implicitation coefficient for the diffusion of
2508 # -----------------------------------
2509 OPTION_FOR_THE_DIFFUSION_OF_VELOCITIES = SIMP(statut ='o',
2510 # -----------------------------------
2512 into = ["div( nu grad(U) )","1/h div ( h nu grad(U)"],
2513 defaut = "div( nu grad(U) )",
2514 fr = """ 1: Diffusion de la forme div( nu grad(U) ) 2: Diffusion de la forme
2515 1/h div ( h nu grad(U) )""",
2516 ang = """ 1: Diffusion in the form div( nu grad(U) ) 2: Diffusion in the form
2517 1/h div ( h nu grad(U) )""",
2521 # -----------------------------------
2522 AUTOMATIC_DIFFERENTIATION = FACT(statut='o',
2523 # -----------------------------------
2524 # -----------------------------------
2525 NUMBER_OF_DIFFERENTIATORS = SIMP(statut ='o',
2526 # -----------------------------------
2529 fr = """ Definit le nombre de differentiateurs utilisateurs.""",
2530 ang = """ Defines the number of user differentiators""",
2532 # -----------------------------------
2533 NAMES_OF_DIFFERENTIATORS = SIMP(statut ='o',
2534 # -----------------------------------
2535 typ = 'TXM', min= 2, max= 2,
2536 fr = """ Noms des differentiateurs utilisateurs en 32 caracteres, 16 pour le
2537 nom, 16 pour l''unite""",
2538 ang = """ Name of user differentiators in 32 characters, 16 for the name, 16 for
2542 # -----------------------------------
2543 ADVANCED = FACT(statut='o',
2544 # -----------------------------------
2545 # -----------------------------------
2546 MATRIX_STORAGE = SIMP(statut ='o',
2547 # -----------------------------------
2549 into = ["classical EBE","Edge-based storage"],
2550 defaut = "Edge-based storage",
2551 fr = """ 1 : EBE classique 3 : Stockage par segments""",
2552 ang = """ 1 : classical EBE 3 : Edge-based storage""",
2554 # -----------------------------------
2555 MATRIX_VECTOR_PRODUCT = SIMP(statut ='o',
2556 # -----------------------------------
2559 fr = """ 1 : classique 2 : frontal attention, avec 2, il faut une numerotation
2560 speciale des points""",
2561 ang = """ 1 : classic 2 : frontal beware, with option 2, a special numbering of
2562 points is required""",
2564 # -----------------------------------
2565 NEWMARK_TIME_INTEGRATION_COEFFICIENT = SIMP(statut ='o',
2566 # -----------------------------------
2569 fr = """ 1. : Euler explicite 0.5 : ordre 2 en temps""",
2570 ang = """ 1. : Euler explicit 0.5 : order 2 in time""",
2572 # -----------------------------------
2573 ZERO = SIMP(statut ='f',
2574 # -----------------------------------
2577 fr = """ Non active pour l''instant.""",
2578 ang = """ Not yet implemented""",
2580 # -----------------------------------
2581 PROPAGATION_OPTION = SIMP(statut ='f',
2582 # -----------------------------------
2585 fr = """ Non active pour l''instant.""",
2586 ang = """ Not yet implemented.""",
2588 # -----------------------------------
2589 OPTION_OF_THE_HYDROSTATIC_RECONSTRUCTION = SIMP(statut ='f',
2590 # -----------------------------------
2593 fr = """ Donne l option de la reconstruction hydrostatique (option utile
2594 uniquement pour les volumes finis): 1: option d Audusse, 2: option de
2596 ang = """ Gives the option for hydrostatic reconstruction (used only for finite
2597 volumes): 1: option of Audusse, 2: option of Noelle""",
2599 # -----------------------------------
2600 CONVERGENCE_STUDY = SIMP(statut ='f',
2601 # -----------------------------------
2604 fr = """Active une etude de convergence par rapport a une
2605 solution analytique sur un maillage fin""",
2606 ang = """Activates a convergence study compared
2607 to an analytical solution on a fine mesh""",
2609 # -----------------------------------
2610 REFINEMENT_LEVELS = SIMP(statut ='f',
2611 # -----------------------------------
2614 fr = """Donne le nombre de raffinements que l''utilisateur
2615 veut utiliser pour l''etude de convergence
2616 (en activant CONVERGENCE). Chaque niveau multiplie par 4 le
2617 nombre d''elements.""",
2618 ang = """Gives the number of refinement levels that the
2619 user wants to use in the convergence study (when activating
2620 CONVERGENCE). Each level multiplies the number of elements by
2625 # -----------------------------------------------------------------------
2626 TURBULENCE = PROC(nom= "TURBULENCE",op = None,
2627 # -----------------------------------------------------------------------
2628 UIinfo = {"groupes": ("CACHE")},
2629 # -----------------------------------
2630 VELOCITY_DIFFUSIVITY = SIMP(statut ='o',
2631 # -----------------------------------
2634 fr = """ Fixe de facon uniforme pour l''ensemble du domaine; la valeur du
2635 coefficient de diffusion de viscosite globale (dynamique + turbulente).
2636 Cette valeur peut avoir une influence non negligeable sur la forme et la
2637 taille des recirculations.""",
2638 ang = """ Sets, in an even way for the whole domain, the value of the
2639 coefficient of global (dynamic+turbulent) viscosity. this value may have
2640 a significant effect both on the shapes and sizes of recirculation
2643 # -----------------------------------
2644 TURBULENCE_MODEL = SIMP(statut ='o',
2645 # -----------------------------------
2647 into = ["CONSTANT VISCOSITY","ELDER","K-EPSILON MODEL","SMAGORINSKI","MIXING LENGTH","SPALART-ALLMARAS"],
2648 defaut = "CONSTANT VISCOSITY",
2649 fr = """ 3 choix sont possibles actuellement : viscosite constante (1) modele
2650 de Elder (2) ou modele k-epsilon (3). Attention : si on choisit
2651 l''option 1 il ne faut pas oublier d''ajuster la valeur du mot-cle
2652 COEFFICIENT DE DIFFUSION DES VITESSES. si on choisit l''option 2 il ne
2653 faut pas oublier d''ajuster les deux valeurs du mot-cle : COEFFICIENTS
2654 ADIMENSIONNELS DE DISPERSION Si on choisit l''option 3; ce meme
2655 parametre doit retrouver sa vraie valeur physique car elle est utilisee
2656 comme telle dans le modele de turbulence""",
2657 ang = """ The current alternatives are as follows: constant viscosity (1)
2658 elder''s model (2) or k-epsilon model (3). NOTE: when option 1 is
2659 chosen, it should be kept in mind that the value of the keyword VELOCITY
2660 DIFFUSIVITY has to be ajusted. When option 2 is chosen, the two values
2661 of key-word : NON-DIMENSIONAL DISPERSION COEFFICIENTS are used When
2662 option 3 is chosen, this parameter should recover its true physical
2663 value, since it is used as such in the turbulence model.""",
2665 # -----------------------------------
2666 b_TURBULENCE_MODELG = BLOC(condition="TURBULENCE_MODEL == 'CONSTANT VISCOSITY'",
2667 # -----------------------------------
2669 # -----------------------------------
2670 b_TURBULENCE_MODELH = BLOC(condition="TURBULENCE_MODEL == 'Elder'",
2671 # -----------------------------------
2672 # -----------------------------------
2673 NON_DIMENSIONAL_DISPERSION_COEFFICIENTS = SIMP(statut ='o',
2674 # -----------------------------------
2675 typ = 'R', min= 2, max= 2,
2677 fr = """ coefficients longitudinal et transversal dans la formule de Elder.
2678 Utilises uniquement avec le modele de turbulence 2""",
2679 ang = """ Longitudinal and transversal coefficients in elder s formula. Used
2680 only with turbulence model number 2""",
2683 # -----------------------------------
2684 ACCURACY_OF_SPALART_ALLMARAS = SIMP(statut ='f',
2685 # -----------------------------------
2688 fr = """Fixe la precision demandee sur le modele spalart-allmaras pour
2689 le test d''arret dans l''etape de diffusion et termes sources de k et
2691 ang = """Sets the required accuracy for the model spalart-allmaras in
2692 the diffusion and source-terms step of the k-epsilon model.""",
2694 # -----------------------------------
2695 INFORMATION_ABOUT_SPALART_ALLMARAS_MODEL = SIMP(statut ='f',
2696 # -----------------------------------
2699 fr = """si oui les informations du solveur du modele spalart-allmaras
2701 ang = """if yes, informations about solver of spalart-allmaras model
2702 are printed to the listing""",
2704 # -----------------------------------
2705 SOLVER_INFO = FACT(statut='o',
2706 # -----------------------------------
2707 # -----------------------------------
2708 SOLVER_FOR_K_EPSILON_MODEL = SIMP(statut ='o',
2709 # -----------------------------------
2711 into = ["conjugate gradient","conjugate residuals","conjugate gradient on normal equation","minimum error","conjugate gradient squared","conjugate gradient squared stabilised (cgstab)","gmres (see option for the solver for k-epsilon model)","direct"],
2712 defaut = "conjugate gradient",
2713 fr = """ Permet de choisir le solveur utilise pour la resolution du systeme du
2714 modele k-epsilon : 1 : gradient conjugue 2 : residu conjugue 3 :
2715 gradient conjugue sur equation normale 4 : erreur minimale 5 : gradient
2716 conjugue carre 6 : gradient conjugue carre stabilise (cgstab) 7 : gmres
2717 (voir aussi option du solveur pour le modele k-epsilon) 8 : direct""",
2718 ang = """ Makes it possible to select the solver used for solving the system of
2719 the k-epsilon model. 1: conjugate gradient 2: conjugate residuals 3:
2720 conjugate gradient on normal equation 4: minimum error 5: conjugate
2721 gradient squared 6: conjugate gradient squared stabilised (cgstab) 7:
2722 gmres (see option for the solver for k-epsilon model) 8: direct""",
2724 # -----------------------------------
2725 OPTION_FOR_THE_SOLVER_FOR_K_EPSILON_MODEL = SIMP(statut ='o',
2726 # -----------------------------------
2729 fr = """ si le solveur est GMRES (7) le mot cle est la dimension de l''espace
2730 de KRILOV (valeurs conseillees entre 2 et 15)""",
2731 ang = """ WHEN GMRES (7) IS CHOSEN, DIMENSION OF THE KRYLOV SPACE TRY VALUES
2732 BETWEEN 2 AND 15""",
2734 # -----------------------------------
2735 PRECONDITIONING_FOR_K_EPSILON_MODEL = SIMP(statut ='o',
2736 # -----------------------------------
2738 into = ["diagonal","no preconditioning","crout","diagonal and crout"],
2739 defaut = "diagonal",
2740 fr = """ Permet de preconditionner le systeme relatif au modele k-epsilon 0 :
2741 pas de preconditionnement; 2 : preconditionnement diagonal. 7 :
2742 preconditionnement de Crout par element.""",
2743 ang = """ Preconditioning of the linear system in the diffusion step of the
2744 k-epsilon model. 0: no preconditioning 2: diagonal preconditioning 7:
2745 Crout''s preconditioning per element""",
2748 # -----------------------------------
2749 ADVANCED = FACT(statut='o',
2750 # -----------------------------------
2751 # -----------------------------------
2752 TURBULENCE_REGIME_FOR_SOLID_BOUNDARIES = SIMP(statut ='f',
2753 # -----------------------------------
2755 into = ["smooth","rough"],
2757 fr = """ Permet de choisir le regime de turbulence aux parois 1 : regime
2758 turbulent lisse. 2 : regime turbulent rugueux.""",
2759 ang = """ Provided for selecting the type of friction on the walls 1: smooth 2:
2762 # -----------------------------------
2763 INFORMATION_ABOUT_K_EPSILON_MODEL = SIMP(statut ='o',
2764 # -----------------------------------
2767 fr = """ Donne le nombre d''iterations du solveur de l''etape de diffusion et
2768 termes sources du modele k-epsilon.""",
2769 ang = """ Gives the number of iterations of the solver in the diffusion and
2770 source terms step of the k-epsilon model.""",
2772 # -----------------------------------
2773 ADVECTION_OF_K_AND_EPSILON = SIMP(statut ='o',
2774 # -----------------------------------
2777 fr = """ Prise en compte ou non de la convection de k et epsilon.""",
2778 ang = """ The k and epsilon advection is taken into account or ignored.""",
2780 # -----------------------------------
2781 b_ADVECTION_OF_K_AND_EPSILONG = BLOC(condition="ADVECTION_OF_K_AND_EPSILON == True",
2782 # -----------------------------------
2783 # -----------------------------------
2784 SCHEME_FOR_ADVECTION_OF_K_EPSILON = SIMP(statut ='f',
2785 # -----------------------------------
2787 into = ["NO ADVECTION","CHARACTERISTICS","EXPLICIT + SUPG","EXPLICIT LEO POSTMA","EXPLICIT + MURD SCHEME N","EXPLICIT + MURD SCHEME PSI","LEO POSTMA FOR TIDAL FLATS","N-SCHEME FOR TIDAL FLATS","ERIA SCHEME FOR TIDAL FLATS"],
2788 defaut = "CHARACTERISTICS",
2789 fr = """ Choix du schema de convection pour k et epsilon, remplace FORME DE LA
2791 ang = """ Choice of the advection scheme for k and epsilon, replaces TYPE OF
2795 # -----------------------------------
2796 SCHEME_OPTION_FOR_ADVECTION_OF_K_EPSILON = SIMP(statut ='f',
2797 # -----------------------------------
2800 fr = """ Si present remplace et a priorite sur : OPTION POUR LES
2801 CARACTERISTIQUES OPTION DE SUPG Si schema PSI ou N : 1=explicite
2802 2=predicteur-correcteur 3=predicteur-correcteur deuxieme ordre en temps
2804 ang = """ If present replaces and has priority over: OPTION FOR CHARACTERISTICS
2805 SUPG OPTION if N or PSI SCHEME: 1=explicit 2=predictor-corrector 3=
2806 predictor-corrector second-order in time 4= implicit""",
2808 # -----------------------------------
2809 TIME_STEP_REDUCTION_FOR_K_EPSILON_MODEL = SIMP(statut ='f',
2810 # -----------------------------------
2813 fr = """ Coefficient reducteur du pas de temps pour le modele k-epsilon (qui
2814 est normalement identique a celui du systeme hydrodynamique).
2815 Utilisation deconseillee""",
2816 ang = """ Time step reduction coefficient for k-epsilon model (which is normally
2817 same the same as that of the hydrodynamic system) Not recommended for
2821 # -----------------------------------
2822 ACCURACY = FACT(statut='o',
2823 # -----------------------------------
2824 # -----------------------------------
2825 ACCURACY_OF_K = SIMP(statut ='o',
2826 # -----------------------------------
2829 fr = """ Fixe la precision demandee sur k pour le test d''arret dans l''etape
2830 de diffusion et termes sources du modele k-epsilon.""",
2831 ang = """ Sets the required accuracy for computing k in the diffusion and source
2832 terms step of the k-epsilon model.""",
2834 # -----------------------------------
2835 ACCURACY_OF_EPSILON = SIMP(statut ='o',
2836 # -----------------------------------
2839 fr = """ Fixe la precision demandee sur epsilon pour le test d''arret dans
2840 l''etape de diffusion et termes sources de k et epsilon.""",
2841 ang = """ Sets the required accuracy for computing epsilon in the diffusion and
2842 source-terms step of the k-epsilon model.""",
2844 # -----------------------------------
2845 MAXIMUM_NUMBER_OF_ITERATIONS_FOR_K_AND_EPSILON = SIMP(statut ='o',
2846 # -----------------------------------
2849 fr = """ Fixe le nombre maximum d''iterations accepte lors de la resolution du
2850 systeme diffusion-termes sources du modele k-epsilon.""",
2851 ang = """ Sets the maximum number of iterations that are acceptable when solving
2852 the diffusion source-terms step of the k-epsilon model.""",
2856 # -----------------------------------------------------------------------
2857 TIDAL_FLATS_INFO = PROC(nom= "TIDAL_FLATS_INFO",op = None,
2858 # -----------------------------------------------------------------------
2859 # -----------------------------------
2860 TIDAL_FLATS = SIMP(statut ='o',
2861 # -----------------------------------
2864 fr = """ permet de supprimer les tests sur les bancs decouvrants, dans les cas
2865 ou l''on est certain qu''il n''y en aura pas. En cas de doute : oui""",
2866 ang = """ When no, the specific treatments for tidal flats are by-passed. This
2867 spares time, but of course you must be sure that you have no tidal
2870 # -----------------------------------
2871 b_TIDAL_FLATSG = BLOC(condition="TIDAL_FLATS == True",
2872 # -----------------------------------
2873 # -----------------------------------
2874 OPTION_FOR_THE_TREATMENT_OF_TIDAL_FLATS = SIMP(statut ='o',
2875 # -----------------------------------
2877 into = ["EQUATIONS SOLVED EVERYWHERE WITH CORRECTION ON TIDAL FLATS","DRY ELEMENTS FROZEN","LIKE 1 BUT WITH POROSITY (DEFINA METHOD)"],
2878 defaut = "EQUATIONS SOLVED EVERYWHERE WITH CORRECTION ON TIDAL FLATS",
2879 fr = """ Utilise si BANCS DECOUVRANTS est vrai 1 : EQUATIONS RESOLUES PARTOUT
2880 AVEC CORRECTION SUR LES BANCS DECOUVRANTS 2 : GEL DES ELEMENTS
2881 DECOUVRANTS 3 : COMME 1 MAIS AVEC POROSITE (METHODE DEFINA)""",
2882 ang = """ Used if TIDAL FLATS is true 1 : EQUATIONS SOLVED EVERYWHERE WITH
2883 CORRECTION ON TIDAL FLATS 2 : DRY ELEMENTS FROZEN 3 : LIKE 1 BUT WITH
2884 POROSITY (DEFINA METHOD)""",
2886 # -----------------------------------
2887 b_OPTION_FOR_THE_TREATMENT_OF_TIDAL_FLATSG = BLOC(condition="OPTION_FOR_THE_TREATMENT_OF_TIDAL_FLATS == 'EQUATIONS SOLVED EVERYWHERE WITH CORRECTION ON TIDAL FLATS'",
2888 # -----------------------------------
2889 # -----------------------------------
2890 TREATMENT_OF_NEGATIVE_DEPTHS = SIMP(statut ='o',
2891 # -----------------------------------
2893 into = ["SMOOTHING","FLUX CONTROL"],
2894 defaut = "SMOOTHING",
2895 fr = """ Seulement avec OPTION DE TRAITEMENT DES BANCS DECOUVRANTS = 1 0 : pas
2896 de traitement 1 : lissage 2 : limitation des flux""",
2897 ang = """ Only with OPTION FOR THE TREATMENT OF TIDAL FLATS=1 0: no treatment
2898 1:smoothing 2:flux control""",
2901 # -----------------------------------
2902 THRESHOLD_FOR_NEGATIVE_DEPTHS = SIMP(statut ='o',
2903 # -----------------------------------
2906 fr = """ En dessous du seuil, les hauteurs negatives sont lissees""",
2907 ang = """ Below the threshold the negative depths are smoothed""",
2909 # -----------------------------------
2910 THRESHOLD_DEPTH_FOR_RECEDING_PROCEDURE = SIMP(statut ='o',
2911 # -----------------------------------
2914 fr = """ Si > 0., declenche la procedure de ressuyage qui evite le
2915 franchissement parasite des digues mal discretisees""",
2916 ang = """ If > 0., will trigger the receding procedure that avoids overwhelming
2917 of dykes which are too loosely discretised""",
2919 # -----------------------------------
2920 H_CLIPPING = SIMP(statut ='o',
2921 # -----------------------------------
2924 fr = """ Determine si l''on desire ou non limiter par valeur inferieure la
2925 hauteur d''eau H (dans le cas des bancs decouvrants par exemple).""",
2926 ang = """ Determines whether limiting the water depth H by a lower value
2927 desirable or not. (for instance in the case of tidal flats) This
2928 key-word may have an influence on mass conservation since the truncation
2929 of depth is equivalent to adding mass.""",
2931 # -----------------------------------
2932 b_H_CLIPPINGG = BLOC(condition="H_CLIPPING == True",
2933 # -----------------------------------
2934 # -----------------------------------
2935 MINIMUM_VALUE_OF_DEPTH = SIMP(statut ='o',
2936 # -----------------------------------
2939 fr = """ Fixe la valeur minimale de a lorsque l''option CLIPPING DE H est
2941 ang = """ Sets the minimum H value when option H CLIPPING is implemented. Not
2942 fully implemented.""",
2947 # -----------------------------------------------------------------------
2948 TRACERS = PROC(nom= "TRACERS",op = None,
2949 # -----------------------------------------------------------------------
2950 # -----------------------------------
2951 BOUNDARY_CONDITIONS_FOR_TRACERS = FACT(statut='o',
2952 # -----------------------------------
2953 # -----------------------------------
2954 PRESCRIBED_TRACERS_VALUES = SIMP(statut ='o',
2955 # -----------------------------------
2956 typ = 'R', max='**',
2957 fr = """ Valeurs du traceur imposees aux frontieres liquides entrantes. Lire la
2958 partie du mode d''emploi consacree aux conditions aux limites""",
2959 ang = """ Tracer values prescribed at the inflow boundaries. Read the usermanual
2960 section dealing with the boundary conditions""",
2963 # -----------------------------------
2964 SETTING = FACT(statut='o',
2965 # -----------------------------------
2966 # -----------------------------------
2967 NUMBER_OF_TRACERS = SIMP(statut ='o',
2968 # -----------------------------------
2971 fr = """ Definit le nombre de traceurs.""",
2972 ang = """ Defines the number of tracers""",
2974 # -----------------------------------
2975 NAMES_OF_TRACERS = SIMP(statut ='o',
2976 # -----------------------------------
2977 typ = 'TXM', min=0, max='**',
2978 fr = """ Noms des traceurs en 32 caracteres, 16 pour le nom 16 pour l''unite""",
2979 ang = """ Name of tracers in 32 characters, 16 for the name, 16 for the unit.""",
2981 # -----------------------------------
2982 INITIAL_VALUES_OF_TRACERS = SIMP(statut ='o',
2983 # -----------------------------------
2984 typ = 'R', min=0, max='**',
2986 fr = """ Fixe la valeur initiale du traceur.""",
2987 ang = """ Sets the initial value of the tracer.""",
2989 # -----------------------------------
2990 DENSITY_EFFECTS = SIMP(statut ='o',
2991 # -----------------------------------
2994 fr = """ PRISE EN COMPTE DU GRADIENT HORIZONTAL DE DENSITE LE TRACEUR EST ALORS
2996 ang = """ THE HORIZONTAL GRADIENT OF DENSITY IS TAKEN INTO ACCOUNT THE TRACER IS
2997 THEN THE SALINITY""",
2999 # -----------------------------------
3000 b_DENSITY_EFFECTSG = BLOC(condition="DENSITY_EFFECTS == True",
3001 # -----------------------------------
3002 # -----------------------------------
3003 MEAN_TEMPERATURE = SIMP(statut ='o',
3004 # -----------------------------------
3007 fr = """ TEMPERATURE DE REFERENCE POUR LE CALCUL DES EFFETS DE DENSITE A
3008 UTILISER AVEC LE MOT-CLE "EFFETS DE DENSITE".""",
3009 ang = """ REFERENCE TEMPERATURE FOR DENSITY EFFECTS TO BE USED WITH THE KEY-WORD
3010 "DENSITY EFFECTS".""",
3013 # -----------------------------------
3014 b_DENSITY_EFFECTSH = BLOC(condition="DENSITY_EFFECTS == True",
3015 # -----------------------------------
3016 # -----------------------------------
3017 Consigne = SIMP(statut ="o", homo="information", typ="TXM",
3018 # -----------------------------------
3019 defaut = "The first tracer must be the salinity in kg/m3"),
3022 # -----------------------------------
3023 SOLVER_TRA = FACT(statut='o',
3024 # -----------------------------------
3025 # -----------------------------------
3026 SOLVER_FOR_DIFFUSION_OF_TRACERS = SIMP(statut ='o',
3027 # -----------------------------------
3028 typ = 'TXM', min=0, max='**',
3029 into = ["conjugate gradient","conjugate residual","conjugate gradient on a normal equation","minimum error","squared conjugate gradient","cgstab","gmres (see option for the solver for tracer diffusion)","direct"],
3030 defaut = ["conjugate gradient","conjugate gradient"],
3031 fr = """ 1 : gradient conjugue 2 : residu conjugue 3 : gradient conjugue sur
3032 equation normale 4 : erreur minimale 5 : gradient conjugue carre""",
3033 ang = """ 1 : conjugate gradient 2 : conjugate gradient 3 : conjugate gradient
3034 on a normal equation 4 : minimum error 5 : squared conjugate gradient 6
3035 : cgstab 7 : gmres (see option for the solver for tracer diffusion) 8 :
3038 # -----------------------------------
3039 SOLVER_OPTION_FOR_TRACERS_DIFFUSION = SIMP(statut ='o',
3040 # -----------------------------------
3043 fr = """ si le solveur est GMRES (7) le mot cle est la dimension de l''espace
3044 de KRILOV (valeurs conseillees entre 2 et 15)""",
3045 ang = """ WHEN GMRES (7) IS CHOSEN, DIMENSION OF THE KRYLOV SPACE TRY VALUES
3046 BETWEEN 2 AND 15""",
3048 # -----------------------------------
3049 PRECONDITIONING_FOR_DIFFUSION_OF_TRACERS = SIMP(statut ='o',
3050 # -----------------------------------
3052 into = ["diagonal","no preconditioning ","crout","diagonal and crout"],
3053 defaut = "diagonal",
3054 fr = """ Permet de preconditionner le systeme relatif au traceur. Memes
3055 definition et possibilites que pour le mot-cle PRECONDITIONNEMENT. 0 :
3056 pas de preconditionnement; 2 : preconditionnement diagonal. 7 : Crout
3058 ang = """ Preconditioning of the linear system in the tracer diffusion step.
3059 Same definition and possibilities as for the keyword PRECONDITIONING 0:
3060 no preconditioning 2: diagonal preconditioning 7: Crout''s
3061 preconditioning per element.""",
3064 # -----------------------------------
3065 ACCURACY_TRA = FACT(statut='o',
3066 # -----------------------------------
3067 # -----------------------------------
3068 ACCURACY_FOR_DIFFUSION_OF_TRACERS = SIMP(statut ='o',
3069 # -----------------------------------
3072 fr = """ Fixe la precision demandee pour le calcul de la diffusion du traceur.""",
3073 ang = """ Sets the required accuracy for computing the tracer diffusion.""",
3075 # -----------------------------------
3076 MAXIMUM_NUMBER_OF_ITERATIONS_FOR_DIFFUSION_OF_TRACERS = SIMP(statut ='o',
3077 # -----------------------------------
3080 fr = """ Limite le nombre d''iterations du solveur a chaque pas de temps pour
3081 le calcul de la diffusion du traceur.""",
3082 ang = """ Limits the number of solver iterations at each time step for the
3083 diffusion of tracer.""",
3086 # -----------------------------------
3087 SOURCES_TRA = FACT(statut='o',
3088 # -----------------------------------
3089 # -----------------------------------
3090 VALUES_OF_THE_TRACERS_AT_THE_SOURCES = SIMP(statut ='o',
3091 # -----------------------------------
3092 typ = 'R', min=0, max='**',
3093 fr = """ Valeurs des traceurs a chacune des sources""",
3094 ang = """ Values of the tracers at the sources""",
3097 # -----------------------------------
3098 METEOROLOGY_TRA = FACT(statut='f',
3099 # -----------------------------------
3100 # -----------------------------------
3101 VALUES_OF_TRACERS_IN_THE_RAIN = SIMP(statut ='o',
3102 # -----------------------------------
3103 typ = 'R', min= 2, max= 2,
3104 fr = """generalement ce traceur est la temperature, dans ce cas
3105 cette valeur est a modifier, sinon la valeur 0 est raisonnable""",
3106 ang = """most often, this tracer is temperature, in this case
3107 this value should be modified, otherwise, default value of 0 seems
3111 # -----------------------------------
3112 NUMERICAL = FACT(statut='o',
3113 # -----------------------------------
3114 # -----------------------------------
3115 ADVECTION_OF_TRACERS = SIMP(statut ='o',
3116 # -----------------------------------
3119 fr = """ Prise en compte ou non de la convection du traceur passif.""",
3120 ang = """ The advection of the passive tracer is taken into account or ignored.""",
3122 # -----------------------------------
3123 b_ADVECTION_OF_TRACERSG = BLOC(condition="ADVECTION_OF_TRACERS == True",
3124 # -----------------------------------
3125 # -----------------------------------
3126 SCHEME_FOR_ADVECTION_OF_TRACERS = SIMP(statut ='o',
3127 # -----------------------------------
3128 typ = 'TXM', min=0, max='**',
3129 into = ["NO ADVECTION","CHARACTERISTICS","EXPLICIT + SUPG","EXPLICIT LEO POSTMA","EXPLICIT + MURD SCHEME N","EXPLICIT + MURD SCHEME PSI","LEO POSTMA FOR TIDAL FLATS","N-SCHEME FOR TIDAL FLATS","ERIA SCHEME FOR TIDAL FLATS"],
3130 defaut = "CHARACTERISTICS",
3131 fr = """ Choix du schema de convection pour les traceurs, remplace FORME DE LA
3133 ang = """ Choice of the advection scheme for the tracers, replaces TYPE OF
3137 # -----------------------------------
3138 IMPLICITATION_COEFFICIENT_OF_TRACERS = SIMP(statut ='o',
3139 # -----------------------------------
3142 fr = """ Fixe la valeur du coefficient d''implicitation du traceur""",
3143 ang = """ Sets the value of the implicitation coefficient for the tracer""",
3145 # -----------------------------------
3146 DIFFUSION_OF_TRACERS = SIMP(statut ='o',
3147 # -----------------------------------
3150 fr = """ Prise en compte ou non de la diffusion du traceur passif.""",
3151 ang = """ The diffusion of the passive tracer is taken into account or ignored.""",
3153 # -----------------------------------
3154 b_DIFFUSION_OF_TRACERSG = BLOC(condition="DIFFUSION_OF_TRACERS == True",
3155 # -----------------------------------
3156 # -----------------------------------
3157 COEFFICIENT_FOR_DIFFUSION_OF_TRACERS = SIMP(statut ='o',
3158 # -----------------------------------
3161 fr = """ Fixe la valeur du coefficient de diffusion du traceur. L''influence de
3162 ce parametre sur l''evolution du traceur dans le temps est importante.""",
3163 ang = """ Sets the value of the tracer diffusivity.""",
3166 # -----------------------------------
3167 OPTION_FOR_THE_DIFFUSION_OF_TRACERS = SIMP(statut ='o',
3168 # -----------------------------------
3170 into = ["div( nu grad(T) )","1/h div ( h nu grad(T)"],
3171 defaut = "div( nu grad(T) )",
3172 fr = """ 1: Diffusion de la forme div( nu grad(T) ) 2: Diffusion de la forme
3173 1/h div ( h nu grad(T) )""",
3174 ang = """ 1: Diffusion in the form div( nu grad(T) ) 2: Diffusion in the form
3175 1/h div ( h nu grad(T) )""",
3177 # -----------------------------------
3178 SCHEME_OPTION_FOR_ADVECTION_OF_TRACERS = SIMP(statut ='o',
3179 # -----------------------------------
3182 fr = """ Si present remplace et a priorite sur : OPTION POUR LES
3183 CARACTERISTIQUES OPTION DE SUPG Si schema PSI ou N : 1=explicite
3184 2=predicteur-correcteur 3=predicteur-correcteur deuxieme ordre en temps
3186 ang = """ If present replaces and has priority over: OPTION FOR CHARACTERISTICS
3187 SUPG OPTION if N or PSI SCHEME: 1=explicit 2=predictor-corrector 3=
3188 predictor-corrector second-order in time 4= implicit""",
3190 # -----------------------------------
3191 MASS_LUMPING_ON_TRACERS = SIMP(statut ='o',
3192 # -----------------------------------
3195 fr = """ Fixe le taux de mass-lumping effectue sur le traceur.""",
3196 ang = """ Sets the amount of mass-lumping that is performed on the tracer.""",
3199 # -----------------------------------
3200 DEGRADATION = FACT(statut='o',
3201 # -----------------------------------
3202 # -----------------------------------
3203 LAW_OF_TRACERS_DEGRADATION = SIMP(statut ='o',
3204 # -----------------------------------
3205 typ = 'TXM', min= 2, max= 2,
3206 into = ["NO DEGRADATION","F(T90) LAW"],
3207 defaut = ["NO DEGRADATION","NO DEGRADATION"],
3208 fr = """ Prise en compte d''une loi de decroissance des traceurs""",
3209 ang = """ Take in account a law for tracers decrease""",
3211 # -----------------------------------
3212 b_LAW_OF_TRACERS_DEGRADATIONG = BLOC(condition="LAW_OF_TRACERS_DEGRADATION == 'F(T90) LAW'",
3213 # -----------------------------------
3214 # -----------------------------------
3215 COEFFICIENT_1_FOR_LAW_OF_TRACERS_DEGRADATION = SIMP(statut ='o',
3216 # -----------------------------------
3217 typ = 'R', min= 2, max= 2,
3218 fr = """ Coefficient 1 de la loi de decroissance des traceurs""",
3219 ang = """ Coefficient 1 of law for tracers decrease""",
3224 # -----------------------------------------------------------------------
3225 PARTICLE_TRANSPORT = PROC(nom= "PARTICLE_TRANSPORT",op = None,
3226 # -----------------------------------------------------------------------
3227 # -----------------------------------
3228 DROGUES = FACT(statut='f',
3229 # -----------------------------------
3230 # -----------------------------------
3231 NUMBER_OF_DROGUES = SIMP(statut ='o',
3232 # -----------------------------------
3235 fr = """ Permet d''effectuer un suivi de flotteurs""",
3236 ang = """ Number of drogues in the computation. The user must then fill the
3237 subroutine FLOT specifying the coordinates of the starting points, their
3238 departure and arrival times. The trajectory of drogues is recorded in
3239 the BINARY RESULTS FILE that must be given in the steering file""",
3241 # -----------------------------------
3242 b_NUMBER_OF_DROGUESG = BLOC(condition="NUMBER_OF_DROGUES != 0",
3243 # -----------------------------------
3244 # -----------------------------------
3245 DROGUES_FILE = SIMP(statut ='o',
3246 # -----------------------------------
3247 typ = ('Fichier','All Files (*)','Sauvegarde'),
3249 fr = """ Fichier de resultat avec les positions des flotteurs""",
3250 ang = """ Results file with positions of drogues""",
3252 # -----------------------------------
3253 PRINTOUT_PERIOD_FOR_DROGUES = SIMP(statut ='o',
3254 # -----------------------------------
3257 fr = """ Nombre de pas de temps entre 2 sorties de positions de flotteurs dans
3258 le fichier des resultats binaire supplementaire N affecte pas la qualite
3259 du calcul de la trajectoire""",
3260 ang = """ Number of time steps between 2 outputs of drogues positions in the
3265 # -----------------------------------
3266 ALGAES = FACT(statut='f',
3267 # -----------------------------------
3268 # -----------------------------------
3269 ALGAE_TRANSPORT_MODEL = SIMP(statut ='o',
3270 # -----------------------------------
3273 fr = """ Si oui, les flotteurs seront des algues""",
3274 ang = """ If yes, the floats or particles will be algae""",
3276 # -----------------------------------
3277 b_ALGAE_TRANSPORT_MODELG = BLOC(condition="ALGAE_TRANSPORT_MODEL == True",
3278 # -----------------------------------
3279 # -----------------------------------
3280 ALGAE_TYPE = SIMP(statut ='o',
3281 # -----------------------------------
3283 into = ["SPHERE","IRIDAEA FLACCIDA (CLOSE TO ULVA)","PELVETIOPSIS LIMITATA","GIGARTINA LEPTORHYNCHOS"],
3285 fr = """ Type des algues. Pour le choix 1 les algues seront modelisees comme
3286 des spheres, pour les autres choix voir Gaylord et al. (1994).""",
3287 ang = """ Algae type. For choice 1 the algae particles will be modeled as
3288 spheres, and for the other choices see Gaylord et al. (1994)""",
3290 # -----------------------------------
3291 DIAMETER_OF_ALGAE = SIMP(statut ='o',
3292 # -----------------------------------
3295 fr = """ Diametre des algues en m""",
3296 ang = """ Diametre of algae in m""",
3298 # -----------------------------------
3299 DENSITY_OF_ALGAE = SIMP(statut ='o',
3300 # -----------------------------------
3303 fr = """ Masse volumique des algues en kg/m3""",
3304 ang = """ Density of algae in kg/m3""",
3306 # -----------------------------------
3307 THICKNESS_OF_ALGAE = SIMP(statut ='o',
3308 # -----------------------------------
3311 fr = """ Epaisseur des algues en m""",
3312 ang = """ Thickness of algae in m""",
3316 # -----------------------------------
3317 OIL_SPILL = FACT(statut='f',
3318 # -----------------------------------
3319 # -----------------------------------
3320 OIL_SPILL_MODEL = SIMP(statut ='o',
3321 # -----------------------------------
3324 fr = """ POUR DECLENCHER LE MODELE DE DERIVE DE NAPPES, DANS CE CAS LE FICHIER
3325 DE COMMANDES MIGRHYCAR EST NECESSAIRE""",
3326 ang = """ WILL TRIGGER THE OIL SPILL MODEL, IN THIS CASE THE MIGRHYCAR STEERING
3329 # -----------------------------------
3330 b_OIL_SPILL_MODELG = BLOC(condition="OIL_SPILL_MODEL == True",
3331 # -----------------------------------
3332 # -----------------------------------
3333 OIL_SPILL_STEERING_FILE = SIMP(statut ='o',
3334 # -----------------------------------
3335 typ = ('Fichier','All Files (*)'),
3337 fr = """ Contient les donnees pour le modele de derive de nappes""",
3338 ang = """ Contains data for the oil spill model""",
3342 # -----------------------------------
3343 BROWNIAN_MOTION = FACT(statut='f',
3344 # -----------------------------------
3345 # -----------------------------------
3346 STOCHASTIC_DIFFUSION_MODEL = SIMP(statut ='o',
3347 # -----------------------------------
3349 into = ["No model","brownian movement"],
3350 defaut = "No model",
3351 fr = """ Pour les particules : flotteurs, hydrocarbures""",
3352 ang = """ Meant for particles: drogues, oil spills""",
3355 # -----------------------------------
3356 LAGRANGIAN_DRIFTS = FACT(statut='f',
3357 # -----------------------------------
3358 # -----------------------------------
3359 NUMBER_OF_LAGRANGIAN_DRIFTS = SIMP(statut ='o',
3360 # -----------------------------------
3363 fr = """ Permet d''effectuer simultanement plusieurs calculs de derives
3364 lagrangiennes initiees a des pas differents""",
3365 ang = """ Provided for performing several computations of lagrangian drifts
3366 starting at different times. Add A and G in the VARIABLES FOR GRAPHIC
3367 PRINTOUTS key-word""",
3369 # -----------------------------------
3370 b_NUMBER_OF_LAGRANGIAN_DRIFTSG = BLOC(condition="NUMBER_OF_LAGRANGIAN_DRIFS != 0",
3371 # -----------------------------------
3372 # -----------------------------------
3373 Consigne = SIMP(statut ="o", homo="information", typ="TXM",
3374 # -----------------------------------
3375 defaut = "Add 'drift along x (m)' and 'drift along y (m)' in VARIABLES FOR GRAPHIC PRINTOUTS"),
3379 # -----------------------------------------------------------------------
3380 HYDRAULIC_STRUCTURES = PROC(nom= "HYDRAULIC_STRUCTURES",op = None,
3381 # -----------------------------------------------------------------------
3382 # -----------------------------------
3383 WEIRS = FACT(statut='f',
3384 # -----------------------------------
3385 # -----------------------------------
3386 NUMBER_OF_WEIRS = SIMP(statut ='o',
3387 # -----------------------------------
3390 fr = """ Nombre de seuils qui seront traites par des conditions aux limites.
3391 Ces seuils doivent etre decrits comme des frontieres du domaine de
3392 calcul, et leurs caracteristiques sont donnees dans le fichier de
3393 donnees des seuils (voir la documentation ecrite)""",
3394 ang = """ Number of weirs that will be treated by boundary conditions. They must
3395 be described as boundaries of the domain and their features are given in
3396 the weir data file (see written documentation)""",
3398 # -----------------------------------
3399 b_NUMBER_OF_WEIRSG = BLOC(condition="NUMBER_OF_WEIRS != 0",
3400 # -----------------------------------
3401 # -----------------------------------
3402 WEIRS_DATA_FILE = SIMP(statut ='o',
3403 # -----------------------------------
3404 typ = ('Fichier','All Files (*)'),
3406 fr = """ Fichier de description des seuils presents dans le modele""",
3407 ang = """ Description of weirs existing in the model""",
3409 # -----------------------------------
3410 TYPE_OF_WEIRS = SIMP(statut ='o',
3411 # -----------------------------------
3413 into = ["HORIZONTAL WITH SAME NUMBER OF NODES UPSTREAM/DOWNSTREAM","GENERAL"],
3414 defaut = "HORIZONTAL WITH SAME NUMBER OF NODES UPSTREAM/DOWNSTREAM",
3415 fr = """ Méthode de traitement des seuils. Deux Solutions:
3416 - HORIZONTAL AVEC MEME NOMBRE DE NOEUDS AMONT/AVAL (Solution historique
3418 - GENERALE (Nouvelle solution avec pts sources)""",
3419 ang = """ Method for treatment of weirs. Two options:
3420 - HORIZONTAL WITH SAME NUMBER OF NODES UPSTREAM/DOWNSTREAM (Historical
3422 - GENERAL (New solution with sources points""",
3426 # -----------------------------------
3427 SIPHONS = FACT(statut='f',
3428 # -----------------------------------
3429 # -----------------------------------
3430 NUMBER_OF_SIPHONS = SIMP(statut ='f',
3431 # -----------------------------------
3434 fr = """ Nombre de siphons traites comme des termes sources ou puits. Ces
3435 siphons doivent etre decrits comme des sources dans le fichier cas.
3436 Leurs caracteristiques sont donnees dans le fichier de donnees des
3437 siphons (voir la documentation ecrite)""",
3438 ang = """ Number of culverts treated as source terms. They must be described as
3439 sources in the domain and their features are given in the culvert data
3440 file (see written documentation)""",
3442 # -----------------------------------
3443 b_NUMBER_OF_SIPHONSG = BLOC(condition="NUMBER_OF_SIPHONS != 0",
3444 # -----------------------------------
3445 # -----------------------------------
3446 SIPHONS_DATA_FILE = SIMP(statut ='o',
3447 # -----------------------------------
3448 typ = ('Fichier','All Files (*)'),
3450 fr = """ Fichier de description des siphons presents dans le modele""",
3451 ang = """ Description of culvert existing in the model""",
3455 # -----------------------------------
3456 CULVERTS = FACT(statut='f',
3457 # -----------------------------------
3458 # -----------------------------------
3459 NUMBER_OF_CULVERTS = SIMP(statut ='o',
3460 # -----------------------------------
3463 fr = """ Nombre de buses ou ponts traites comme des termes sources ou puits.
3464 Ces buses doivent etre decrits comme des sources dans le fichier cas.
3465 Leurs caracteristiques sont donnees dans le fichier de donnees des buses
3466 (voir la documentation ecrite)""",
3467 ang = """ Number of culverts or bridges treated as source terms. They must be
3468 described as sources in the domain and their features are given in the
3469 culverts data file (see written documentation)""",
3471 # -----------------------------------
3472 b_NUMBER_OF_CULVERTSG = BLOC(condition="NUMBER_OF_CULVERTS != 0",
3473 # -----------------------------------
3474 # -----------------------------------
3475 CULVERTS_DATA_FILE = SIMP(statut ='o',
3476 # -----------------------------------
3477 typ = ('Fichier','All Files (*)'),
3479 fr = """ Fichier de description des buses/ponts presents dans le modele""",
3480 ang = """ Description of tubes/bridges existing in the model""",
3483 # -----------------------------------
3484 OPTION_FOR_CULVERTS = SIMP(statut ='f',
3485 # -----------------------------------
3488 fr = """Option pour le traitement des buses. Il existe deux formulations
3490 ang = """Option for the treatment of culverts. There are two options in
3494 # -----------------------------------
3495 BREACHES = FACT(statut='f',
3496 # -----------------------------------
3497 # -----------------------------------
3498 BREACH = SIMP(statut ='o',
3499 # -----------------------------------
3502 fr = """ Prise en compte de breches dans le calcul par modification
3503 altimetrique dans le maillage. La description des breches se fait avec
3504 le fichier de donnees des breches.""",
3505 ang = """ Take in account some breaches during the computation by modifying the
3506 bottom level of the mesh. Brech description is done with the breaches
3509 # -----------------------------------
3510 b_BREACHG = BLOC(condition="BREACH == True",
3511 # -----------------------------------
3512 # -----------------------------------
3513 BREACHES_DATA_FILE = SIMP(statut ='o',
3514 # -----------------------------------
3515 typ = ('Fichier','All Files (*)'),
3517 fr = """ Fichier de description des breches""",
3518 ang = """ Description of breaches""",
3523 # -----------------------------------------------------------------------
3524 TIDES = PROC(nom= "TIDES",op = None,
3525 # -----------------------------------------------------------------------
3526 # -----------------------------------
3527 BOUNDARY_CONDITIONS = FACT(statut='o',
3528 # -----------------------------------
3529 # -----------------------------------
3530 TIDAL_DATA_BASE = SIMP(statut ='o',
3531 # -----------------------------------
3533 into = ["NO DEFAULT VALUE","JMJ","TPXO","MISCELLANEOUS (LEGOS-NEA, FES20XX, PREVIMER...)"],
3534 defaut = "NO DEFAULT VALUE",
3535 fr = """ Pour JMJ, renseigner la localisation du fichier bdd\_jmj et geofin
3536 dans les mots-cles BASE DE DONNEES DE MAREE et FICHIER DU MODELE DE
3537 MAREE. Pour TPXO, LEGOS-NEA, FES20XX et PREVIMER, l''utilisateur doit
3538 telecharger les fichiers de constantes harmoniques sur internet""",
3539 ang = """ For JMJ, indicate the location of the files bdd\_jmj and geofin with
3540 keywords TIDE DATA BASE and TIDAL MODEL FILE. For TPXO, LEGOS-NEA,
3541 FES20XX and PREVIMER, the user has to download files of harmonic
3542 constituents on the internet""",
3544 # -----------------------------------
3545 b_TIDAL_DATA_BASEG = BLOC(condition="TIDAL_DATA_BASE == 'TPXO'",
3546 # -----------------------------------
3547 # -----------------------------------
3548 MINOR_CONSTITUENTS_INFERENCE = SIMP(statut ='o',
3549 # -----------------------------------
3552 fr = """ Pour la base de donnees TPXO uniquement. Interpolation de composantes
3553 harmoniques mineures a partir de celles lues dans les fichiers d''entree
3554 lies aux mots-cles BASE BINAIRE 1 DE DONNEES DE MAREE et BASE BINAIRE 2
3555 DE DONNEES DE MAREE""",
3556 ang = """ For TPXO tidal data base only. Inference of minor constituents from
3557 the one read in input files linked to keywords BINARY DATABASE 1 FOR
3558 TIDE and BINARY DATABASE 2 FOR TIDE""",
3560 # -----------------------------------
3561 BINARY_DATABASE_1_FOR_TIDE = SIMP(statut ='o',
3562 # -----------------------------------
3563 typ = ('Fichier','All Files (*)'),
3565 fr = """ Base de donnees binaire 1 tiree du fichier du modele de maree. Dans le
3566 cas des donnees satellitaires de TPXO, ce fichier correspond aux donnees
3567 de niveau d''eau, par exemple h\_tpxo7.2""",
3568 ang = """ Binary database 1 extracted from the tidal model file. In the case of
3569 the TPXO satellite altimetry model, this file should be for free surface
3570 level, for instance h\_tpxo7.2""",
3572 # -----------------------------------
3573 BINARY_DATABASE_2_FOR_TIDE = SIMP(statut ='o',
3574 # -----------------------------------
3575 typ = ('Fichier','All Files (*)'),
3577 fr = """ Base de donnees binaire 2 tiree du fichier du modele de maree. Dans le
3578 cas des donnees satellitaires de TPXO, ce fichier correspond aux donnees
3579 de vitesse de marrees, par exemple u\_tpxo7.2""",
3580 ang = """ Binary database 2 extracted from the tidal model file. In the case of
3581 the TPXO satellite altimetry model, this file should be for tidal
3582 velocities, for instance u\_tpxo7.2""",
3585 # -----------------------------------
3586 TIDAL_MODEL_FILE = SIMP(statut ='o',
3587 # -----------------------------------
3588 typ = ('Fichier','All Files (*)'),
3590 fr = """ Fichier de geometrie du modele dont sont extraites les constantes
3592 ang = """ Geometry file of the model from which harmonic constituents are
3595 # -----------------------------------
3596 HARMONIC_CONSTANTS_FILE = SIMP(statut ='o',
3597 # -----------------------------------
3598 typ = ('Fichier','All Files (*)'),
3600 fr = """ Constantes harmoniques extraites du fichier du modele de maree""",
3601 ang = """ Harmonic constants extracted from the tidalmodel file""",
3604 # -----------------------------------
3605 PHYSICAL_PARAMETERS = FACT(statut='o',
3606 # -----------------------------------
3607 # -----------------------------------
3608 TIDE_GENERATING_FORCE = SIMP(statut ='o',
3609 # -----------------------------------
3612 fr = """ Active la prise en compte de la force generatrice de la maree""",
3613 ang = """ The tide generating force is taken into account.""",
3615 # -----------------------------------
3616 b_TIDE_GENERATING_FORCEG = BLOC(condition="TIDE_GENERATING_FORCE == True",
3617 # -----------------------------------
3619 # -----------------------------------
3620 OPTION_FOR_TIDAL_BOUNDARY_CONDITIONS = SIMP(statut ='o',
3621 # -----------------------------------
3622 typ = 'TXM', max='**',
3623 into = ["No tide","Real tide (recommended methodology)","Astronomical tide","Mean spring tide","Mean tide","Mean neap tide","Astronomical neap tide","Real tide (methodology before 2010)"],
3624 fr = """ Option pour les conditions aux limites de maree. Pour des marees
3625 reelles, l option 1 est recommandee. Depuis la version 7.1, ce mot-cle
3626 est un tableau avec une valeur donnee par frontiere liquide, separee par
3627 point-virgules. Ceci permet d''avoir des conditions de maree (ou pas)
3628 calculees sur des frontieres liquides avec vitesses ou hauteur d eau
3629 imposees. Ca evite un conflit lors de l utilisation de seuils dans le
3630 domaine. 0 est le code pour des conditions autres que des conditions de
3631 maree. ATTENTION depuis la version 7.1 ! Les anciens modeles doivent
3632 etre changes si la frontiere de maree n a pas le numero 1. Dans ce cas,
3633 le mot-cle doit etre change et plus de valeurs doivent etre donnees.
3634 Calage possible par les mots-cles COEFFICIENT POUR CALAGE EN MARNAGE et
3635 COEFFICIENT POUR CALAGE EN NIVEAU.""",
3636 ang = """ Option for tidal boundary conditions. For real tides, option 1 is
3637 recommended. This keyword has been an array with a value given per
3638 liquid boundary, separated by semicolons, since version 7.1. This
3639 enables to have tidal conditions (or not) computed on liquid boundaries
3640 with prescribed velocities or depths, avoiding a clash when using weirs
3641 in the domain. 0 codes for conditions other than tidal. BEWARE since
3642 version 7.1! Old models must be changed if their tidal boundary is not
3643 number 1. In that case this keyword must be changed and more values
3644 given. Possible calibration with the keywords COEFFICIENT TO ADJUST
3645 TIDAL RANGE, COEFFICENT TO CALIBRATE TIDAL VELOCITIES, and COEFFICIENT
3646 TO ADJUST SEA LEVEL.""",
3649 # -----------------------------------
3650 CALIBRATION = FACT(statut='o',
3651 # -----------------------------------
3652 # -----------------------------------
3653 GEOGRAPHIC_SYSTEM = SIMP(statut ='o',
3654 # -----------------------------------
3656 into = ["NO DEFAULT VALUE","DEFINED BY USER","WGS84 LONGITUDE/LATITUDE IN REAL DEGREES","WGS84 NORTHERN UTM","WGS84 SOUTHERN UTM","LAMBERT","MERCATOR FOR TELEMAC"],
3657 defaut = "NO DEFAULT VALUE",
3658 fr = """ Systeme de coordonnees geographiques dans lequel est construit le
3659 modele numerique. Indiquer la zone correspondante avec le mot-cle""",
3660 ang = """ Geographic coordinates system in which the numerical model is built.
3661 Indicate the corresponding zone with the keyword""",
3663 # -----------------------------------
3664 b_GEOGRAPHIC_SYSTEMG = BLOC(condition="GEOGRAPHIC_SYSTEM in ['WGS84 NOTHERN UTM','WGS84 SOUTHERN UTM','LAMBERT']",
3665 # -----------------------------------
3666 # -----------------------------------
3667 ZONE_NUMBER_IN_GEOGRAPHIC_SYSTEM = SIMP(statut ='f',
3668 # -----------------------------------
3670 into = ["NO DEFAULT VALUE","LAMBERT 1 NORTH","LAMBERT 2 CENTER","LAMBERT 3 SOUTH","LAMBERT 4 CORSICA","LAMBERT 2 EXTENDED","UTM ZONE, E.G."],
3671 defaut = "NO DEFAULT VALUE",
3672 fr = """ Numero de zone (fuseau ou type de projection) lors de l''utilisation
3673 d''une projection plane. Indiquer le systeme geographique dans lequel
3674 est construit le modele numerique avec le mot-cle SYSTEME GEOGRAPHIQUE""",
3675 ang = """ Number of zone when using a plane projection. Indicate the geographic
3676 system in which the numerical model is built with the keyword GEOGRAPHIC
3680 # -----------------------------------
3681 COEFFICIENT_TO_CALIBRATE_SEA_LEVEL = SIMP(statut ='o',
3682 # -----------------------------------
3685 fr = """ Coefficient pour ajuster le niveau de mer""",
3686 ang = """ Coefficient to calibrate the sea level""",
3688 # -----------------------------------
3689 COEFFICIENT_TO_CALIBRATE_TIDAL_RANGE = SIMP(statut ='o',
3690 # -----------------------------------
3693 fr = """ Coefficient pour ajuster le marnage de l''onde de maree aux frontieres
3695 ang = """ Coefficient to calibrate the tidal range of tidal wave at tidal open
3696 boundary conditions""",
3698 # -----------------------------------
3699 COEFFICIENT_TO_CALIBRATE_TIDAL_VELOCITIES = SIMP(statut ='o',
3700 # -----------------------------------
3703 fr = """ Coefficient pour ajuster les composantes de vitesse de l''onde de
3704 maree aux frontieres maritimes. La valeur par defaut 999999. signifie
3705 que c''est la racine carree du COEFFICIENT DE CALAGE DU MARNAGE qui est
3707 ang = """ Coefficient to calibrate the tidal velocities of tidal wave at tidal
3708 open boundary conditions. Default value 999999. means that the square
3709 root of COEFFICIENT TO CALIBRATE TIDAL RANGE is taken""",
3711 # -----------------------------------
3712 LOCAL_NUMBER_OF_THE_POINT_TO_CALIBRATE_HIGH_WATER = SIMP(statut ='f',
3713 # -----------------------------------
3716 fr = """ Numero local du point entre 1 et le nombre de points de frontiere
3717 maritime (du FICHIER DES CONSTANTES HARMONIQUES) ou les conditions aux
3718 limites de maree sont calculees avec les bases de donnees JMJ, NEA, FES,
3719 PREVIMER (sauf les bases de type TPXO). Les ondes de maree sont
3720 dephasees par rapport a ce point pour debuter le calcul par une pleine
3721 mer (en marees schematiques seulement).""",
3722 ang = """ Local number between 1 and the number of tidal boundary points (of the
3723 HARMONIC CONSTANTS FILE) where the tidal boundary conditions are
3724 computed with JMJ, NEA, FES, PREVIMER databases (except TPXO-type
3725 databases). The tidal constituents have their phase shifted with respect
3726 to this point to start the simulation with a high water (for schematic
3729 # -----------------------------------
3730 GLOBAL_NUMBER_OF_THE_POINT_TO_CALIBRATE_HIGH_WATER = SIMP(statut ='f',
3731 # -----------------------------------
3734 fr = """ Numero global du point par rapport auquel les ondes de maree sont
3735 dephasees pour debuter le calcul par une pleine mer (en marees
3736 schematiques seulement). Ne concerne que les bases de constantes
3737 harmoniques de type TPXO.""",
3738 ang = """ Global number of the point with respect to which the tidal
3739 constituents have their phase shifted to start the calculation with a
3740 high water (for schematic tides only). Only harmonic constants databases
3741 like TPXO are concerned.""",
3745 # -----------------------------------------------------------------------
3746 COUPLING = PROC(nom= "COUPLING",op = None,
3747 # -----------------------------------------------------------------------
3748 # -----------------------------------
3749 COUPLING_WITH = SIMP(statut ='o',
3750 # -----------------------------------
3752 into = ['SISYPHE','TOMAWAC','DELWAQ'],
3754 fr = """ Liste des codes avec lesquels on couple Telemac-2D SISYPHE : couplage
3755 interne avec Sisyphe TOMAWAC : couplage interne avec Tomawac DELWAQ :
3756 sortie de fichiers de resultats pour Delwaq""",
3757 ang = """ List of codes to be coupled with Telemac-2D SISYPHE : internal
3758 coupling with Sisyphe TOMAWAC : internal coupling with Tomawac DELWAQ:
3759 will yield results file for Delwaq""",
3761 # -----------------------------------
3762 NAMES_OF_CLANDESTINE_VARIABLES = SIMP(statut ='f',
3763 # -----------------------------------
3764 typ = 'TXM', min= 2, max= 2,
3765 fr = """ Noms de variables qui ne sont pas utilisees par TELEMAC; mais qui
3766 doivent etre conservees lors de son execution. Ceci peut etre utilise
3767 entre autres lors du couplage de TELEMAC avec un autre code. Les
3768 variables clandestines sont alors des variables propres a l''autre code
3769 et sont rendues dans le fichier de resultats.""",
3770 ang = """ Names of variables that are not used by TELEMAC, but should be
3771 preserved when it is being run. This keyword may be used, for instance
3772 when it if TELEMAC is coupled with another code. Thus, the clandestine
3773 variables belong to the other code and are given back in the results
3776 # -----------------------------------
3777 DELWAQ = FACT(statut='o',
3778 # -----------------------------------
3779 # -----------------------------------
3780 COUPLING_DIRECTORY = SIMP(statut ='f',
3781 # -----------------------------------
3784 fr = """ Nom complet du dossier d echange des fichiers pour couplage de codes""",
3785 ang = """ Name with full path of the directory where the files will be exchanged
3788 # -----------------------------------
3789 DELWAQ_PRINTOUT_PERIOD = SIMP(statut ='f',
3790 # -----------------------------------
3793 fr = """ Periode de sortie des resultats pour Delwaq""",
3794 ang = """ Printout period for Delwaq file""",
3796 # -----------------------------------
3797 VOLUMES_DELWAQ_FILE = SIMP(statut ='f',
3798 # -----------------------------------
3799 typ = ('Fichier','All Files (*)','Sauvegarde'),
3801 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3802 ang = """ Results file for coupling with Delwaq""",
3804 # -----------------------------------
3805 EXCHANGE_AREAS_DELWAQ_FILE = SIMP(statut ='f',
3806 # -----------------------------------
3807 typ = ('Fichier','All Files (*)','Sauvegarde'),
3809 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3810 ang = """ Results file for coupling with Delwaq""",
3812 # -----------------------------------
3813 VERTICAL_FLUXES_DELWAQ_FILE = SIMP(statut ='f',
3814 # -----------------------------------
3815 typ = ('Fichier','All Files (*)','Sauvegarde'),
3817 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3818 ang = """ Results file for coupling with Delwaq""",
3820 # -----------------------------------
3821 SALINITY_DELWAQ_FILE = SIMP(statut ='f',
3822 # -----------------------------------
3823 typ = ('Fichier','All Files (*)','Sauvegarde'),
3825 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3826 ang = """ Results file for coupling with Delwaq""",
3828 # -----------------------------------
3829 BOTTOM_SURFACES_DELWAQ_FILE = SIMP(statut ='f',
3830 # -----------------------------------
3831 typ = ('Fichier','All Files (*)','Sauvegarde'),
3833 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3834 ang = """ Results file for coupling with Delwaq""",
3836 # -----------------------------------
3837 EXCHANGES_BETWEEN_NODES_DELWAQ_FILE = SIMP(statut ='f',
3838 # -----------------------------------
3839 typ = ('Fichier','All Files (*)','Sauvegarde'),
3841 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3842 ang = """ Results file for coupling with Delwaq""",
3844 # -----------------------------------
3845 NODES_DISTANCES_DELWAQ_FILE = SIMP(statut ='f',
3846 # -----------------------------------
3847 typ = ('Fichier','All Files (*)','Sauvegarde'),
3849 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3850 ang = """ Results file for coupling with Delwaq""",
3852 # -----------------------------------
3853 TEMPERATURE_DELWAQ_FILE = SIMP(statut ='f',
3854 # -----------------------------------
3855 typ = ('Fichier','All Files (*)','Sauvegarde'),
3857 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3858 ang = """ Results file for coupling with Delwaq""",
3860 # -----------------------------------
3861 VELOCITY_DELWAQ_FILE = SIMP(statut ='f',
3862 # -----------------------------------
3863 typ = ('Fichier','All Files (*)','Sauvegarde'),
3865 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3866 ang = """ Results file for coupling with Delwaq""",
3868 # -----------------------------------
3869 DIFFUSIVITY_DELWAQ_FILE = SIMP(statut ='f',
3870 # -----------------------------------
3871 typ = ('Fichier','All Files (*)','Sauvegarde'),
3873 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3874 ang = """ Results file for coupling with Delwaq""",
3876 # -----------------------------------
3877 DELWAQ_STEERING_FILE = SIMP(statut ='f',
3878 # -----------------------------------
3879 typ = ('Fichier','All Files (*)','Sauvegarde'),
3881 fr = """ Fichier de resultats pour le couplage avec Delwaq""",
3882 ang = """ Results file for coupling with Delwaq""",
3884 # -----------------------------------
3885 SALINITY_FOR_DELWAQ = SIMP(statut ='f',
3886 # -----------------------------------
3889 fr = """ Decide de la sortie de la salinite pour Delwaq""",
3890 ang = """ Triggers output of salinity for Delwaq""",
3892 # -----------------------------------
3893 TEMPERATURE_FOR_DELWAQ = SIMP(statut ='f',
3894 # -----------------------------------
3897 fr = """ Decide de la sortie de la temperature pour Delwaq""",
3898 ang = """ Triggers output of temperature for Delwaq""",
3900 # -----------------------------------
3901 VELOCITY_FOR_DELWAQ = SIMP(statut ='f',
3902 # -----------------------------------
3905 fr = """ Decide de la sortie de la vitesse pour Delwaq""",
3906 ang = """ Triggers output of velocity for Delwaq""",
3908 # -----------------------------------
3909 DIFFUSIVITY_FOR_DELWAQ = SIMP(statut ='f',
3910 # -----------------------------------
3913 fr = """ Decide de la sortie du coefficient de diffusion pour Delwaq""",
3914 ang = """ Triggers output of diffusion for Delwaq""",
3917 # -----------------------------------
3918 SISYPHE = FACT(statut='o',
3919 # -----------------------------------
3920 # -----------------------------------
3921 SISYPHE_STEERING_FILE = SIMP(statut ='f',
3922 # -----------------------------------
3925 fr = """ Fichier des parametres de Sisyphe en cas de couplage interne""",
3926 ang = """ Sisyphe parameter file in case of internal coupling""",
3928 # -----------------------------------
3929 COUPLING_PERIOD_FOR_SISYPHE = SIMP(statut ='f',
3930 # -----------------------------------
3933 fr = """ pour eviter de faire le couplage a chaque pas de temps""",
3934 ang = """ to avoid coupling at every time-step""",
3937 # -----------------------------------
3938 TOMAWAC = FACT(statut='o',
3939 # -----------------------------------
3940 # -----------------------------------
3941 TOMAWAC_STEERING_FILE = SIMP(statut ='f',
3942 # -----------------------------------
3945 fr = """ Fichier des parametres de Tomawac en cas de couplage interne""",
3946 ang = """ Tomawac parameter file in case of internal coupling""",
3948 # -----------------------------------
3949 COUPLING_PERIOD_FOR_TOMAWAC = SIMP(statut ='f',
3950 # -----------------------------------
3953 fr = """ pour eviter de faire le couplage a chaque pas de temps""",
3954 ang = """ to avoid coupling at every time-step""",
3957 # -----------------------------------
3958 WAQTEL = FACT(statut='o',
3959 # -----------------------------------
3960 # -----------------------------------
3961 WAQTEL_STEERING_FILE = SIMP(statut ='f',
3962 # -----------------------------------
3965 fr = """ fichier des parametres physiques pour les processus de qualite d eau
3966 (internes non ceux de DELWAQ)""",
3967 ang = """ file for physical parameters of waq processes (local ones of
3968 Telemac-tracer not those of DELWAQ)""",
3972 # -----------------------------------------------------------------------
3973 MISC = PROC(nom= "MISC",op = None,
3974 # -----------------------------------------------------------------------
3975 # -----------------------------------
3976 LANGUAGE = SIMP(statut ='f',
3977 # -----------------------------------
3979 into = ["FRANCAIS","ANGLAIS"],
3981 fr = """ 1 : FRANCAIS 2 : ANGLAIS""",
3982 ang = """ 1: FRENCH 2: ENGLISH""",
3985 # -----------------------------------------------------------------------
3986 INTERNAL = PROC(nom= "INTERNAL",op = None,
3987 # -----------------------------------------------------------------------
3988 # -----------------------------------
3989 STEERING_FILE = SIMP(statut ='f',
3990 # -----------------------------------
3991 typ = ('Fichier','All Files (*)'),
3993 fr = """ Nom du fichier contenant les parametres du calcul a realiser.""",
3994 ang = """ Name of the file containing the parameters of the computation Written
3997 # -----------------------------------
3998 DICTIONARY = SIMP(statut ='f',
3999 # -----------------------------------
4000 typ = ('Fichier','All Files (*)'),
4001 defaut = 'telemac2d.dico',
4002 fr = """ Dictionnaire des mots cles.""",
4003 ang = """ Key word dictionary.""",
4005 # -----------------------------------
4006 PARTITIONING_TOOL = SIMP(statut ='f',
4007 # -----------------------------------
4009 into = ['METIS','SCOTCH','PARMETIS','PTSCOTCH'],
4011 fr = """ CHOIX DU PARTITIONNEUR 1 : METIS 2 : SCOTCH 3 : PARMETIS 4 : PTSCOTCH
4013 ang = """ PARTITIONING TOOL SELECTION 1 : METIS 2 : SCOTCH 3 : PARMETIS 4 :
4016 # -----------------------------------
4017 RELEASE = SIMP(statut ='f',
4018 # -----------------------------------
4021 fr = """ Numero de version des bibliotheques utilisees par TELEMAC. SUR UNE
4022 STATION DE TRAVAIL 5 versions sont donnees correspondant a :
4023 TELEMAC,DAMO,UTILE,BIEF,HP""",
4024 ang = """ version number of the libraries used by TELEMAC. ON A WORKSTATION 5
4025 numbers are given, corresponding to the libraries called:
4026 TELEMAC,DAMO,UTILE,BIEF,HP""",
4028 # -----------------------------------
4029 LIST_OF_FILES = SIMP(statut ='f',
4030 # -----------------------------------
4031 typ = 'TXM', min=47, max=47,
4032 defaut = 'STEERING FILE;DICTIONARY;FORTRAN FILE;GEOMETRY FILE;BOUNDARY CONDITIONS FILE;RESULTS FILE;PREVIOUS COMPUTATION FILE;BOTTOM TOPOGRAPHY FILE;BINARY DATA FILE 1;BINARY DATA FILE 2;FORMATTED DATA FILE 1;FORMATTED DATA FILE 2;BINARY RESULTS FILE;FORMATTED RESULTS FILE;REFERENCE FILE;LIQUID BOUNDARIES FILE;FRICTION DATA FILE;VOLUMES DELWAQ FILE;EXCHANGE AREAS DELWAQ FILE;VERTICAL FLUXES DELWAQ FILE;SALINITY DELWAQ FILE;VELOCITY DELWAQ FILE;DIFFUSIVITY DELWAQ FILE;BOTTOM SURFACES DELWAQ FILE;EXCHANGES BETWEEN NODES DELWAQ FILE;NODES DISTANCES DELWAQ FILE;TEMPERATURE DELWAQ FILE;DELWAQ STEERING FILE;STAGE-DISCHARGE CURVES FILE;SOURCES FILE;SECTIONS INPUT FILE;SECTIONS OUTPUT FILE;OIL SPILL STEERING FILE;HARMONIC CONSTANTS FILE;TIDAL MODEL FILE;ASCII DATABASE FOR TIDE;BINARY DATABASE 1 FOR TIDE;BINARY DATABASE 2 FOR TIDE;WEIRS DATA FILE;SIPHONS DATA FILE;CULVERTS DATA FILE;BREACHES DATA FILE;DROGUES FILE;ZONES FILE;FLUXLINE INPUT FILE;ASCII ATMOSPHERIC DATA FILE;BINARY ATMOSPHERIC DATA FILE',
4033 fr = """ Noms des fichiers exploites par le code""",
4034 ang = """ File names of the used files""",
4036 # -----------------------------------
4037 DESCRIPTION_OF_LIBRARIES = SIMP(statut ='f',
4038 # -----------------------------------
4039 typ = 'TXM', min=11, max=11,
4040 defaut = 'builds|PPP|lib|telemac2dMMMVVV.LLL;builds|PPP|lib|sisypheMMMVVV.LLL;builds|PPP|lib|tomawacMMMVVV.LLL;builds|PPP|lib|nestorMMMVVV.LLL;builds|PPP|lib|waqtelMMMVVV.LLL;builds|PPP|lib|stbtelMMMVVV.LLL;builds|PPP|lib|biefMMMVVV.LLL;builds|PPP|lib|hermesMMMVVV.LLL;builds|PPP|lib|damoMMMVVV.LLL;builds|PPP|lib|parallelMMMVVV.LLL;builds|PPP|lib|specialMMMVVV.LLL',
4041 fr = """ Description des librairies de T2D""",
4042 ang = """ LIBRARIES description""",
4044 # -----------------------------------
4045 DEFAULT_EXECUTABLE = SIMP(statut ='f',
4046 # -----------------------------------
4048 defaut = 'builds|PPP|bin|telemac2dMMMVVV.exe',
4049 fr = """ Executable par defaut de T2D""",
4050 ang = """ Default executable for T2D""",
4052 # -----------------------------------
4053 DEFAULT_PARALLEL_EXECUTABLE = SIMP(statut ='f',
4054 # -----------------------------------
4056 defaut = 'builds|PPP|bin|telemac2dMMMVVV.exe',
4057 fr = """ Executable parallele par defaut de T2D""",
4058 ang = """ Default parallel executable for T2D""",
4061 Ordre_Des_Commandes = (
4062 'COMPUTATION_ENVIRONMENT',
4064 'GENERAL_PARAMETERS',
4065 'NUMERICAL_PARAMETERS',
4069 'PARTICLE_TRANSPORT',
4070 'HYDRAULIC_STRUCTURES',
4075 Classement_Commandes_Ds_Arbre = (
4076 'COMPUTATION_ENVIRONMENT',
4078 'GENERAL_PARAMETERS',
4079 'NUMERICAL_PARAMETERS',
4083 'PARTICLE_TRANSPORT',
4084 'HYDRAULIC_STRUCTURES',