1 |
(PID.TID 0000.0001) |
2 |
(PID.TID 0000.0001) // ====================================================== |
3 |
(PID.TID 0000.0001) // MITgcm UV |
4 |
(PID.TID 0000.0001) // ========= |
5 |
(PID.TID 0000.0001) // ====================================================== |
6 |
(PID.TID 0000.0001) // execution environment starting up... |
7 |
(PID.TID 0000.0001) |
8 |
(PID.TID 0000.0001) // MITgcmUV version: checkpoint65q |
9 |
(PID.TID 0000.0001) // Build user: mlosch |
10 |
(PID.TID 0000.0001) // Build host: bkli04l006 |
11 |
(PID.TID 0000.0001) // Build date: Wed Dec 16 11:53:23 CET 2015 |
12 |
(PID.TID 0000.0001) |
13 |
(PID.TID 0000.0001) // ======================================================= |
14 |
(PID.TID 0000.0001) // Execution Environment parameter file "eedata" |
15 |
(PID.TID 0000.0001) // ======================================================= |
16 |
(PID.TID 0000.0001) ># Example "eedata" file |
17 |
(PID.TID 0000.0001) ># Lines beginning "#" are comments |
18 |
(PID.TID 0000.0001) ># nTx - No. threads per process in X |
19 |
(PID.TID 0000.0001) ># nTy - No. threads per process in Y |
20 |
(PID.TID 0000.0001) > &EEPARMS |
21 |
(PID.TID 0000.0001) > nTx=1, |
22 |
(PID.TID 0000.0001) > nTy=1, |
23 |
(PID.TID 0000.0001) > / |
24 |
(PID.TID 0000.0001) ># Note: Some systems use & as the namelist terminator (as shown here). |
25 |
(PID.TID 0000.0001) ># Other systems use a / character. |
26 |
(PID.TID 0000.0001) |
27 |
(PID.TID 0000.0001) // ======================================================= |
28 |
(PID.TID 0000.0001) // Computational Grid Specification ( see files "SIZE.h" ) |
29 |
(PID.TID 0000.0001) // ( and "eedata" ) |
30 |
(PID.TID 0000.0001) // ======================================================= |
31 |
(PID.TID 0000.0001) nPx = 1 ; /* No. processes in X */ |
32 |
(PID.TID 0000.0001) nPy = 1 ; /* No. processes in Y */ |
33 |
(PID.TID 0000.0001) nSx = 2 ; /* No. tiles in X per process */ |
34 |
(PID.TID 0000.0001) nSy = 2 ; /* No. tiles in Y per process */ |
35 |
(PID.TID 0000.0001) sNx = 40 ; /* Tile size in X */ |
36 |
(PID.TID 0000.0001) sNy = 21 ; /* Tile size in Y */ |
37 |
(PID.TID 0000.0001) OLx = 3 ; /* Tile overlap distance in X */ |
38 |
(PID.TID 0000.0001) OLy = 3 ; /* Tile overlap distance in Y */ |
39 |
(PID.TID 0000.0001) nTx = 1 ; /* No. threads in X per process */ |
40 |
(PID.TID 0000.0001) nTy = 1 ; /* No. threads in Y per process */ |
41 |
(PID.TID 0000.0001) Nr = 1 ; /* No. levels in the vertical */ |
42 |
(PID.TID 0000.0001) Nx = 80 ; /* Total domain size in X ( = nPx*nSx*sNx ) */ |
43 |
(PID.TID 0000.0001) Ny = 42 ; /* Total domain size in Y ( = nPy*nSy*sNy ) */ |
44 |
(PID.TID 0000.0001) nTiles = 4 ; /* Total no. tiles per process ( = nSx*nSy ) */ |
45 |
(PID.TID 0000.0001) nProcs = 1 ; /* Total no. processes ( = nPx*nPy ) */ |
46 |
(PID.TID 0000.0001) nThreads = 1 ; /* Total no. threads per process ( = nTx*nTy ) */ |
47 |
(PID.TID 0000.0001) usingMPI = F ; /* Flag used to control whether MPI is in use */ |
48 |
(PID.TID 0000.0001) /* note: To execute a program with MPI calls */ |
49 |
(PID.TID 0000.0001) /* it must be launched appropriately e.g */ |
50 |
(PID.TID 0000.0001) /* "mpirun -np 64 ......" */ |
51 |
(PID.TID 0000.0001) useCoupler= F ;/* Flag used to control communications with */ |
52 |
(PID.TID 0000.0001) /* other model components, through a coupler */ |
53 |
(PID.TID 0000.0001) debugMode = F ; /* print debug msg. (sequence of S/R calls) */ |
54 |
(PID.TID 0000.0001) printMapIncludesZeros= F ; /* print zeros in Std.Output maps */ |
55 |
(PID.TID 0000.0001) maxLengthPrt1D= 65 /* maxLength of 1D array printed to StdOut */ |
56 |
(PID.TID 0000.0001) |
57 |
(PID.TID 0000.0001) // ====================================================== |
58 |
(PID.TID 0000.0001) // Mapping of tiles to threads |
59 |
(PID.TID 0000.0001) // ====================================================== |
60 |
(PID.TID 0000.0001) // -o- Thread 1, tiles ( 1: 2, 1: 2) |
61 |
(PID.TID 0000.0001) |
62 |
(PID.TID 0000.0001) // ====================================================== |
63 |
(PID.TID 0000.0001) // Tile <-> Tile connectvity table |
64 |
(PID.TID 0000.0001) // ====================================================== |
65 |
(PID.TID 0000.0001) // Tile number: 000001 (process no. = 000000) |
66 |
(PID.TID 0000.0001) // WEST: Tile = 000002, Process = 000000, Comm = put |
67 |
(PID.TID 0000.0001) // bi = 000002, bj = 000001 |
68 |
(PID.TID 0000.0001) // EAST: Tile = 000002, Process = 000000, Comm = put |
69 |
(PID.TID 0000.0001) // bi = 000002, bj = 000001 |
70 |
(PID.TID 0000.0001) // SOUTH: Tile = 000003, Process = 000000, Comm = put |
71 |
(PID.TID 0000.0001) // bi = 000001, bj = 000002 |
72 |
(PID.TID 0000.0001) // NORTH: Tile = 000003, Process = 000000, Comm = put |
73 |
(PID.TID 0000.0001) // bi = 000001, bj = 000002 |
74 |
(PID.TID 0000.0001) // Tile number: 000002 (process no. = 000000) |
75 |
(PID.TID 0000.0001) // WEST: Tile = 000001, Process = 000000, Comm = put |
76 |
(PID.TID 0000.0001) // bi = 000001, bj = 000001 |
77 |
(PID.TID 0000.0001) // EAST: Tile = 000001, Process = 000000, Comm = put |
78 |
(PID.TID 0000.0001) // bi = 000001, bj = 000001 |
79 |
(PID.TID 0000.0001) // SOUTH: Tile = 000004, Process = 000000, Comm = put |
80 |
(PID.TID 0000.0001) // bi = 000002, bj = 000002 |
81 |
(PID.TID 0000.0001) // NORTH: Tile = 000004, Process = 000000, Comm = put |
82 |
(PID.TID 0000.0001) // bi = 000002, bj = 000002 |
83 |
(PID.TID 0000.0001) // Tile number: 000003 (process no. = 000000) |
84 |
(PID.TID 0000.0001) // WEST: Tile = 000004, Process = 000000, Comm = put |
85 |
(PID.TID 0000.0001) // bi = 000002, bj = 000002 |
86 |
(PID.TID 0000.0001) // EAST: Tile = 000004, Process = 000000, Comm = put |
87 |
(PID.TID 0000.0001) // bi = 000002, bj = 000002 |
88 |
(PID.TID 0000.0001) // SOUTH: Tile = 000001, Process = 000000, Comm = put |
89 |
(PID.TID 0000.0001) // bi = 000001, bj = 000001 |
90 |
(PID.TID 0000.0001) // NORTH: Tile = 000001, Process = 000000, Comm = put |
91 |
(PID.TID 0000.0001) // bi = 000001, bj = 000001 |
92 |
(PID.TID 0000.0001) // Tile number: 000004 (process no. = 000000) |
93 |
(PID.TID 0000.0001) // WEST: Tile = 000003, Process = 000000, Comm = put |
94 |
(PID.TID 0000.0001) // bi = 000001, bj = 000002 |
95 |
(PID.TID 0000.0001) // EAST: Tile = 000003, Process = 000000, Comm = put |
96 |
(PID.TID 0000.0001) // bi = 000001, bj = 000002 |
97 |
(PID.TID 0000.0001) // SOUTH: Tile = 000002, Process = 000000, Comm = put |
98 |
(PID.TID 0000.0001) // bi = 000002, bj = 000001 |
99 |
(PID.TID 0000.0001) // NORTH: Tile = 000002, Process = 000000, Comm = put |
100 |
(PID.TID 0000.0001) // bi = 000002, bj = 000001 |
101 |
(PID.TID 0000.0001) |
102 |
(PID.TID 0000.0001) INI_PARMS: opening model parameter file "data" |
103 |
(PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data |
104 |
(PID.TID 0000.0001) // ======================================================= |
105 |
(PID.TID 0000.0001) // Parameter file "data" |
106 |
(PID.TID 0000.0001) // ======================================================= |
107 |
(PID.TID 0000.0001) ># ==================== |
108 |
(PID.TID 0000.0001) ># | Model parameters | |
109 |
(PID.TID 0000.0001) ># ==================== |
110 |
(PID.TID 0000.0001) ># |
111 |
(PID.TID 0000.0001) > &PARM01 |
112 |
(PID.TID 0000.0001) > tRef= -1.62, |
113 |
(PID.TID 0000.0001) > sRef= 30., |
114 |
(PID.TID 0000.0001) > no_slip_sides=.FALSE., |
115 |
(PID.TID 0000.0001) > no_slip_bottom=.TRUE., |
116 |
(PID.TID 0000.0001) >#bottomDragLinear=1.E-3, |
117 |
(PID.TID 0000.0001) > bottomDragQuadratic=5.E-3, |
118 |
(PID.TID 0000.0001) > viscAr=3.E-2, |
119 |
(PID.TID 0000.0001) > viscAh=3.E+2, |
120 |
(PID.TID 0000.0001) > HeatCapacity_Cp = 3986., |
121 |
(PID.TID 0000.0001) > rhoNil = 1030., |
122 |
(PID.TID 0000.0001) > rhoConstFresh = 1000., |
123 |
(PID.TID 0000.0001) > eosType='LINEAR', |
124 |
(PID.TID 0000.0001) > tAlpha=2.E-4, |
125 |
(PID.TID 0000.0001) > sBeta= 0., |
126 |
(PID.TID 0000.0001) > staggerTimeStep=.TRUE., |
127 |
(PID.TID 0000.0001) > saltStepping=.FALSE., |
128 |
(PID.TID 0000.0001) > tempStepping=.FALSE., |
129 |
(PID.TID 0000.0001) >#tempAdvection=.FALSE., |
130 |
(PID.TID 0000.0001) > momStepping=.FALSE., |
131 |
(PID.TID 0000.0001) > f0=0.e-4, |
132 |
(PID.TID 0000.0001) > beta=0., |
133 |
(PID.TID 0000.0001) > useJamartWetPoints=.TRUE., |
134 |
(PID.TID 0000.0001) > rigidLid=.FALSE., |
135 |
(PID.TID 0000.0001) > implicitFreeSurface=.TRUE., |
136 |
(PID.TID 0000.0001) >#exactConserv=.TRUE., |
137 |
(PID.TID 0000.0001) > convertFW2Salt=-1, |
138 |
(PID.TID 0000.0001) > readBinaryPrec=64, |
139 |
(PID.TID 0000.0001) > writeBinaryPrec=64, |
140 |
(PID.TID 0000.0001) >#globalFiles=.TRUE., |
141 |
(PID.TID 0000.0001) > useSingleCpuIO=.TRUE., |
142 |
(PID.TID 0000.0001) >#debugLevel=4, |
143 |
(PID.TID 0000.0001) > / |
144 |
(PID.TID 0000.0001) > |
145 |
(PID.TID 0000.0001) ># Elliptic solver parameters |
146 |
(PID.TID 0000.0001) > &PARM02 |
147 |
(PID.TID 0000.0001) > cg2dMaxIters=500, |
148 |
(PID.TID 0000.0001) > cg2dTargetResidual=1.E-12, |
149 |
(PID.TID 0000.0001) > / |
150 |
(PID.TID 0000.0001) > |
151 |
(PID.TID 0000.0001) ># Time stepping parameters |
152 |
(PID.TID 0000.0001) > &PARM03 |
153 |
(PID.TID 0000.0001) > startTime=0.0, |
154 |
(PID.TID 0000.0001) >#endTime=432000., |
155 |
(PID.TID 0000.0001) > deltaT=1800.0, |
156 |
(PID.TID 0000.0001) > abEps=0.1, |
157 |
(PID.TID 0000.0001) > forcing_In_AB = .FALSE., |
158 |
(PID.TID 0000.0001) > pChkptFreq=3600000., |
159 |
(PID.TID 0000.0001) > dumpFreq = 432000., |
160 |
(PID.TID 0000.0001) > monitorFreq=864000., |
161 |
(PID.TID 0000.0001) > monitorSelect=2, |
162 |
(PID.TID 0000.0001) > nTimeSteps=12, |
163 |
(PID.TID 0000.0001) > / |
164 |
(PID.TID 0000.0001) > |
165 |
(PID.TID 0000.0001) ># Gridding parameters |
166 |
(PID.TID 0000.0001) > &PARM04 |
167 |
(PID.TID 0000.0001) > usingCartesianGrid=.TRUE., |
168 |
(PID.TID 0000.0001) > delX=80*5.E3, |
169 |
(PID.TID 0000.0001) > delY=42*5.E3, |
170 |
(PID.TID 0000.0001) > ygOrigin=-110.E3, |
171 |
(PID.TID 0000.0001) >#delR= 20., 30., 50., |
172 |
(PID.TID 0000.0001) > delR= 10., |
173 |
(PID.TID 0000.0001) > / |
174 |
(PID.TID 0000.0001) > |
175 |
(PID.TID 0000.0001) ># Input datasets |
176 |
(PID.TID 0000.0001) > &PARM05 |
177 |
(PID.TID 0000.0001) > bathyFile = 'bathy_3c.bin', |
178 |
(PID.TID 0000.0001) > uVelInitFile = 'uVel_3c0.bin', |
179 |
(PID.TID 0000.0001) > vVelInitFile = 'vVel_3c0.bin', |
180 |
(PID.TID 0000.0001) > pSurfInitFile = 'eta_3c0.bin', |
181 |
(PID.TID 0000.0001) >#uVelInitFile = 'uVel_3c1.bin', |
182 |
(PID.TID 0000.0001) >#vVelInitFile = 'vVel_3c1.bin', |
183 |
(PID.TID 0000.0001) >#pSurfInitFile = 'eta_3c1.bin', |
184 |
(PID.TID 0000.0001) >#bathyFile = 'channel.bin', |
185 |
(PID.TID 0000.0001) >#uVelInitFile = 'const+40.bin', |
186 |
(PID.TID 0000.0001) >#vVelInitFile = 'const-10.bin', |
187 |
(PID.TID 0000.0001) > / |
188 |
(PID.TID 0000.0001) |
189 |
(PID.TID 0000.0001) INI_PARMS ; starts to read PARM01 |
190 |
(PID.TID 0000.0001) INI_PARMS ; read PARM01 : OK |
191 |
(PID.TID 0000.0001) INI_PARMS ; starts to read PARM02 |
192 |
(PID.TID 0000.0001) INI_PARMS ; read PARM02 : OK |
193 |
(PID.TID 0000.0001) INI_PARMS ; starts to read PARM03 |
194 |
(PID.TID 0000.0001) INI_PARMS ; read PARM03 : OK |
195 |
(PID.TID 0000.0001) INI_PARMS ; starts to read PARM04 |
196 |
(PID.TID 0000.0001) INI_PARMS ; read PARM04 : OK |
197 |
(PID.TID 0000.0001) INI_PARMS ; starts to read PARM05 |
198 |
(PID.TID 0000.0001) INI_PARMS ; read PARM05 : OK |
199 |
(PID.TID 0000.0001) INI_PARMS: finished reading file "data" |
200 |
(PID.TID 0000.0001) PACKAGES_BOOT: opening data.pkg |
201 |
(PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.pkg |
202 |
(PID.TID 0000.0001) // ======================================================= |
203 |
(PID.TID 0000.0001) // Parameter file "data.pkg" |
204 |
(PID.TID 0000.0001) // ======================================================= |
205 |
(PID.TID 0000.0001) ># Packages |
206 |
(PID.TID 0000.0001) > &PACKAGES |
207 |
(PID.TID 0000.0001) > useEXF = .TRUE., |
208 |
(PID.TID 0000.0001) > useSEAICE = .TRUE., |
209 |
(PID.TID 0000.0001) > useThSIce = .TRUE., |
210 |
(PID.TID 0000.0001) > useDiagnostics=.TRUE., |
211 |
(PID.TID 0000.0001) > / |
212 |
(PID.TID 0000.0001) |
213 |
(PID.TID 0000.0001) PACKAGES_BOOT: finished reading data.pkg |
214 |
(PID.TID 0000.0001) PACKAGES_BOOT: On/Off package Summary |
215 |
-------- pkgs with a standard "usePKG" On/Off switch in "data.pkg": -------- |
216 |
pkg/cal compiled and used ( useCAL = T ) |
217 |
pkg/exf compiled and used ( useEXF = T ) |
218 |
pkg/seaice compiled and used ( useSEAICE = T ) |
219 |
pkg/thsice compiled and used ( useThSIce = T ) |
220 |
pkg/diagnostics compiled and used ( useDiagnostics = T ) |
221 |
-------- pkgs without standard "usePKG" On/Off switch in "data.pkg": -------- |
222 |
pkg/generic_advdiff compiled but not used ( useGAD = F ) |
223 |
pkg/mom_common compiled but not used ( momStepping = F ) |
224 |
pkg/mom_vecinv compiled but not used ( +vectorInvariantMomentum = F ) |
225 |
pkg/mom_fluxform compiled but not used ( & not vectorInvariantMom = F ) |
226 |
pkg/monitor compiled and used ( monitorFreq > 0. = T ) |
227 |
pkg/debug compiled but not used ( debugMode = F ) |
228 |
pkg/rw compiled and used |
229 |
pkg/mdsio compiled and used |
230 |
(PID.TID 0000.0001) PACKAGES_BOOT: End of package Summary |
231 |
(PID.TID 0000.0001) |
232 |
(PID.TID 0000.0001) CAL_READPARMS: opening data.cal |
233 |
(PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.cal |
234 |
(PID.TID 0000.0001) // ======================================================= |
235 |
(PID.TID 0000.0001) // Parameter file "data.cal" |
236 |
(PID.TID 0000.0001) // ======================================================= |
237 |
(PID.TID 0000.0001) ># |
238 |
(PID.TID 0000.0001) ># ******************* |
239 |
(PID.TID 0000.0001) ># Calendar Parameters |
240 |
(PID.TID 0000.0001) ># ******************* |
241 |
(PID.TID 0000.0001) > &CAL_NML |
242 |
(PID.TID 0000.0001) > TheCalendar='gregorian', |
243 |
(PID.TID 0000.0001) ># TheCalendar='model', |
244 |
(PID.TID 0000.0001) > startDate_1=19790101, |
245 |
(PID.TID 0000.0001) > startDate_2=000000, |
246 |
(PID.TID 0000.0001) > / |
247 |
(PID.TID 0000.0001) |
248 |
(PID.TID 0000.0001) CAL_READPARMS: finished reading data.cal |
249 |
(PID.TID 0000.0001) EXF_READPARMS: opening data.exf |
250 |
(PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.exf |
251 |
(PID.TID 0000.0001) // ======================================================= |
252 |
(PID.TID 0000.0001) // Parameter file "data.exf" |
253 |
(PID.TID 0000.0001) // ======================================================= |
254 |
(PID.TID 0000.0001) ># |
255 |
(PID.TID 0000.0001) ># ********************* |
256 |
(PID.TID 0000.0001) ># External Forcing Data |
257 |
(PID.TID 0000.0001) ># ********************* |
258 |
(PID.TID 0000.0001) > &EXF_NML_01 |
259 |
(PID.TID 0000.0001) ># |
260 |
(PID.TID 0000.0001) > useExfCheckRange = .TRUE., |
261 |
(PID.TID 0000.0001) >#repeatPeriod = 2635200.0, |
262 |
(PID.TID 0000.0001) > exf_iprec = 64, |
263 |
(PID.TID 0000.0001) > exf_monFreq = 86400000., |
264 |
(PID.TID 0000.0001) >#useRelativeWind = .TRUE., |
265 |
(PID.TID 0000.0001) ># |
266 |
(PID.TID 0000.0001) > / |
267 |
(PID.TID 0000.0001) > |
268 |
(PID.TID 0000.0001) ># ********************* |
269 |
(PID.TID 0000.0001) > &EXF_NML_02 |
270 |
(PID.TID 0000.0001) ># |
271 |
(PID.TID 0000.0001) >#ustressstartdate1 = 19781216, |
272 |
(PID.TID 0000.0001) >#ustressstartdate2 = 180000, |
273 |
(PID.TID 0000.0001) >#ustressperiod = 0.0, |
274 |
(PID.TID 0000.0001) ># |
275 |
(PID.TID 0000.0001) >#vstressstartdate1 = 19781216, |
276 |
(PID.TID 0000.0001) >#vstressstartdate2 = 180000, |
277 |
(PID.TID 0000.0001) >#vstressperiod = 0.0, |
278 |
(PID.TID 0000.0001) ># |
279 |
(PID.TID 0000.0001) > atempstartdate1 = 19781216, |
280 |
(PID.TID 0000.0001) > atempstartdate2 = 180000, |
281 |
(PID.TID 0000.0001) > atempperiod = 0.0, |
282 |
(PID.TID 0000.0001) ># |
283 |
(PID.TID 0000.0001) > aqhstartdate1 = 19781216, |
284 |
(PID.TID 0000.0001) > aqhstartdate2 = 180000, |
285 |
(PID.TID 0000.0001) > aqhperiod = 0.0, |
286 |
(PID.TID 0000.0001) ># |
287 |
(PID.TID 0000.0001) > precipstartdate1 = 19781216, |
288 |
(PID.TID 0000.0001) > precipstartdate2 = 180000, |
289 |
(PID.TID 0000.0001) > precipperiod = 0.0, |
290 |
(PID.TID 0000.0001) ># |
291 |
(PID.TID 0000.0001) > uwindstartdate1 = 19781216, |
292 |
(PID.TID 0000.0001) > uwindstartdate2 = 180000, |
293 |
(PID.TID 0000.0001) > uwindperiod = 0.0, |
294 |
(PID.TID 0000.0001) ># |
295 |
(PID.TID 0000.0001) > vwindstartdate1 = 19781216, |
296 |
(PID.TID 0000.0001) > vwindstartdate2 = 180000, |
297 |
(PID.TID 0000.0001) > vwindperiod = 0.0, |
298 |
(PID.TID 0000.0001) ># |
299 |
(PID.TID 0000.0001) > swdownstartdate1 = 19781216, |
300 |
(PID.TID 0000.0001) > swdownstartdate2 = 180000, |
301 |
(PID.TID 0000.0001) > swdownperiod = 0.0, |
302 |
(PID.TID 0000.0001) ># |
303 |
(PID.TID 0000.0001) > lwdownstartdate1 = 19781216, |
304 |
(PID.TID 0000.0001) > lwdownstartdate2 = 180000, |
305 |
(PID.TID 0000.0001) > lwdownperiod = 0.0, |
306 |
(PID.TID 0000.0001) ># |
307 |
(PID.TID 0000.0001) > climsststartdate1 = 19781216, |
308 |
(PID.TID 0000.0001) > climsststartdate2 = 180000, |
309 |
(PID.TID 0000.0001) > climsstperiod = 0.0, |
310 |
(PID.TID 0000.0001) >#climsstTauRelax = 2592000., |
311 |
(PID.TID 0000.0001) ># |
312 |
(PID.TID 0000.0001) > climsssstartdate1 = 19781216, |
313 |
(PID.TID 0000.0001) > climsssstartdate2 = 180000, |
314 |
(PID.TID 0000.0001) > climsssperiod = 0.0, |
315 |
(PID.TID 0000.0001) >#climsssTauRelax = 2592000., |
316 |
(PID.TID 0000.0001) ># |
317 |
(PID.TID 0000.0001) >#ustressfile = ' ', |
318 |
(PID.TID 0000.0001) >#vstressfile = ' ', |
319 |
(PID.TID 0000.0001) >#atempfile = 'tair_4x.bin', |
320 |
(PID.TID 0000.0001) >#aqhfile = 'qa70_4x.bin', |
321 |
(PID.TID 0000.0001) > uwindfile = 'windx.bin', |
322 |
(PID.TID 0000.0001) >#vwindfile = 'windy.bin', |
323 |
(PID.TID 0000.0001) >#precipfile = 'const_00.bin', |
324 |
(PID.TID 0000.0001) >#lwdownfile = 'dlw_250.bin', |
325 |
(PID.TID 0000.0001) >#swdownfile = 'dsw_100.bin', |
326 |
(PID.TID 0000.0001) >#runoffFile = ' ' |
327 |
(PID.TID 0000.0001) >#climsstfile = 'tocn.bin', |
328 |
(PID.TID 0000.0001) >#climsssfile = 'socn.bin', |
329 |
(PID.TID 0000.0001) > / |
330 |
(PID.TID 0000.0001) > |
331 |
(PID.TID 0000.0001) ># ********************* |
332 |
(PID.TID 0000.0001) > &EXF_NML_03 |
333 |
(PID.TID 0000.0001) >#exf_offset_atemp=5; |
334 |
(PID.TID 0000.0001) > / |
335 |
(PID.TID 0000.0001) > |
336 |
(PID.TID 0000.0001) ># ********************* |
337 |
(PID.TID 0000.0001) ># old open64 compiler (4.2.1) cannot skip this namelist to read in the next one; |
338 |
(PID.TID 0000.0001) ># comment out this namelist (not read). |
339 |
(PID.TID 0000.0001) >#&EXF_NML_04 |
340 |
(PID.TID 0000.0001) >#& |
341 |
(PID.TID 0000.0001) > |
342 |
(PID.TID 0000.0001) ># ********************* |
343 |
(PID.TID 0000.0001) > &EXF_NML_OBCS |
344 |
(PID.TID 0000.0001) > / |
345 |
(PID.TID 0000.0001) |
346 |
(PID.TID 0000.0001) EXF_READPARMS: reading EXF_NML_01 |
347 |
(PID.TID 0000.0001) EXF_READPARMS: reading EXF_NML_02 |
348 |
(PID.TID 0000.0001) EXF_READPARMS: reading EXF_NML_03 |
349 |
(PID.TID 0000.0001) EXF_READPARMS: finished reading data.exf |
350 |
(PID.TID 0000.0001) |
351 |
(PID.TID 0000.0001) SEAICE_READPARMS: opening data.seaice |
352 |
(PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.seaice |
353 |
(PID.TID 0000.0001) // ======================================================= |
354 |
(PID.TID 0000.0001) // Parameter file "data.seaice" |
355 |
(PID.TID 0000.0001) // ======================================================= |
356 |
(PID.TID 0000.0001) ># SEAICE parameters |
357 |
(PID.TID 0000.0001) > &SEAICE_PARM01 |
358 |
(PID.TID 0000.0001) >#SEAICE_tensilFac = 1.0, |
359 |
(PID.TID 0000.0001) >#SEAICEuseStrImpCpl = .TRUE., |
360 |
(PID.TID 0000.0001) >#SEAICE_OLx = 2, |
361 |
(PID.TID 0000.0001) >#SEAICE_OLy = 2, |
362 |
(PID.TID 0000.0001) > usePW79thermodynamics=.FALSE., |
363 |
(PID.TID 0000.0001) > SEAICE_strength = 2.6780e+04, |
364 |
(PID.TID 0000.0001) > OCEAN_drag = 8.1541e-04, |
365 |
(PID.TID 0000.0001) > SEAICE_waterDrag = 5.3508, |
366 |
(PID.TID 0000.0001) > SEAICE_no_Slip = .FALSE., |
367 |
(PID.TID 0000.0001) ># JFNK solver parameters |
368 |
(PID.TID 0000.0001) > SEAICEetaZmethod = 3, |
369 |
(PID.TID 0000.0001) > SEAICEuseJFNK = .TRUE., |
370 |
(PID.TID 0000.0001) > SOLV_MAX_ITERS = 10, |
371 |
(PID.TID 0000.0001) > SEAICEnewtonIterMax = 200, |
372 |
(PID.TID 0000.0001) > SEAICEkrylovIterMax = 50, |
373 |
(PID.TID 0000.0001) > JFNKgamma_nonlin = 1.e-09, |
374 |
(PID.TID 0000.0001) > SEAICE_JFNK_lsIter = 0, |
375 |
(PID.TID 0000.0001) > JFNKres_tFac = 0.5, |
376 |
(PID.TID 0000.0001) > SEAICE_JFNKalpha = 1.5, |
377 |
(PID.TID 0000.0001) >#JFNKgamma_lin_min = 1.e-1, |
378 |
(PID.TID 0000.0001) >#JFNKgamma_lin_max = 0.99, |
379 |
(PID.TID 0000.0001) >#SEAICE_JFNK_tolIter = 1000, |
380 |
(PID.TID 0000.0001) ># end of JFNK solver parameters |
381 |
(PID.TID 0000.0001) >#- to use seaice-advection from pkg/seaice, uncomment following 4 lines: |
382 |
(PID.TID 0000.0001) >#SEAICEadvScheme = 77, |
383 |
(PID.TID 0000.0001) >#AreaFile = 'const100.bin', |
384 |
(PID.TID 0000.0001) >#HeffFile = 'const+20.bin', |
385 |
(PID.TID 0000.0001) >#HsnowFile = 'const_00.bin', |
386 |
(PID.TID 0000.0001) > SEAICEwriteState = .TRUE., |
387 |
(PID.TID 0000.0001) > SEAICE_monFreq = 1800., |
388 |
(PID.TID 0000.0001) > / |
389 |
(PID.TID 0000.0001) > |
390 |
(PID.TID 0000.0001) > &SEAICE_PARM03 |
391 |
(PID.TID 0000.0001) > / |
392 |
(PID.TID 0000.0001) |
393 |
(PID.TID 0000.0001) SEAICE_READPARMS: finished reading data.seaice |
394 |
(PID.TID 0000.0001) THSICE_READPARMS: opening data.ice |
395 |
(PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.ice |
396 |
(PID.TID 0000.0001) // ======================================================= |
397 |
(PID.TID 0000.0001) // Parameter file "data.ice" |
398 |
(PID.TID 0000.0001) // ======================================================= |
399 |
(PID.TID 0000.0001) > &THSICE_CONST |
400 |
(PID.TID 0000.0001) >#- with fractional ice: |
401 |
(PID.TID 0000.0001) > iceMaskMin = 0.001, |
402 |
(PID.TID 0000.0001) > hiMax = 10., |
403 |
(PID.TID 0000.0001) > hsMax = 10., |
404 |
(PID.TID 0000.0001) > dhSnowLin = 0.1, |
405 |
(PID.TID 0000.0001) > fracEnFreez= 0.4, |
406 |
(PID.TID 0000.0001) > hNewIceMax = 1., |
407 |
(PID.TID 0000.0001) > albIceMax = 0.6, |
408 |
(PID.TID 0000.0001) > albIceMin = 0.6, |
409 |
(PID.TID 0000.0001) >#albColdSnow= 0.85, |
410 |
(PID.TID 0000.0001) >#albWarmSnow= 0.60, |
411 |
(PID.TID 0000.0001) >#tempSnowAlb= -5., |
412 |
(PID.TID 0000.0001) >#albOldSnow = 0.60, |
413 |
(PID.TID 0000.0001) >#hNewSnowAge= 2.e-3, |
414 |
(PID.TID 0000.0001) >#snowAgTime = 4320000., |
415 |
(PID.TID 0000.0001) >#hAlbIce = 0.44, |
416 |
(PID.TID 0000.0001) >#hAlbSnow = 0.15, |
417 |
(PID.TID 0000.0001) > / |
418 |
(PID.TID 0000.0001) > |
419 |
(PID.TID 0000.0001) > &THSICE_PARM01 |
420 |
(PID.TID 0000.0001) >#StartIceModel=1, |
421 |
(PID.TID 0000.0001) > thSIce_skipThermo=.TRUE., |
422 |
(PID.TID 0000.0001) > thSIceAdvScheme=77, |
423 |
(PID.TID 0000.0001) >#thSIce_diffK =800., |
424 |
(PID.TID 0000.0001) > stressReduction=0., |
425 |
(PID.TID 0000.0001) > thSIceFract_InitFile='const100.bin', |
426 |
(PID.TID 0000.0001) > thSIceThick_InitFile='const+20.bin', |
427 |
(PID.TID 0000.0001) >#thSIce_diagFreq=2592000., |
428 |
(PID.TID 0000.0001) > thSIce_monFreq =21600., |
429 |
(PID.TID 0000.0001) > thSIce_monFreq =1800., |
430 |
(PID.TID 0000.0001) > / |
431 |
(PID.TID 0000.0001) > |
432 |
(PID.TID 0000.0001) |
433 |
(PID.TID 0000.0001) THSICE_READPARMS: read THSICE_CONST |
434 |
(PID.TID 0000.0001) THSICE_READPARMS: read THSICE_PARM01 |
435 |
ThSI: rhos = 3.3000000000000E+02 |
436 |
ThSI: rhoi = 9.0000000000000E+02 |
437 |
ThSI: rhosw = 1.0300000000000E+03 |
438 |
ThSI: rhofw = 1.0000000000000E+03 |
439 |
ThSI: floodFac = 3.9393939393939E-01 |
440 |
ThSI: cpIce = 2.1060000000000E+03 |
441 |
ThSI: cpWater = 3.9860000000000E+03 |
442 |
ThSI: kIce = 2.0300000000000E+00 |
443 |
ThSI: kSnow = 3.0000000000000E-01 |
444 |
ThSI: bMeltCoef = 6.0000000000000E-03 |
445 |
ThSI: Lfresh = 3.3400000000000E+05 |
446 |
ThSI: qsnow = 3.3400000000000E+05 |
447 |
ThSI: albColdSnow = 8.5000000000000E-01 |
448 |
ThSI: albWarmSnow = 7.0000000000000E-01 |
449 |
ThSI: tempSnowAlb = -1.0000000000000E+01 |
450 |
ThSI: albOldSnow = 5.5000000000000E-01 |
451 |
ThSI: hNewSnowAge = 2.0000000000000E-03 |
452 |
ThSI: snowAgTime = 4.3200000000000E+06 |
453 |
ThSI: albIceMax = 6.0000000000000E-01 |
454 |
ThSI: albIceMin = 6.0000000000000E-01 |
455 |
ThSI: hAlbIce = 5.0000000000000E-01 |
456 |
ThSI: hAlbSnow = 3.0000000000000E-01 |
457 |
ThSI: i0swFrac = 3.0000000000000E-01 |
458 |
ThSI: ksolar = 1.5000000000000E+00 |
459 |
ThSI: dhSnowLin = 1.0000000000000E-01 |
460 |
ThSI: saltIce = 4.0000000000000E+00 |
461 |
ThSI: S_winton = 1.0000000000000E+00 |
462 |
ThSI: mu_Tf = 5.4000000000000E-02 |
463 |
ThSI: Tf0kel = 2.7315000000000E+02 |
464 |
ThSI: Tmlt1 = -5.4000000000000E-02 |
465 |
ThSI: Terrmax = 5.0000000000000E-01 |
466 |
ThSI: nitMaxTsf = 20 |
467 |
ThSI: hIceMin = 1.0000000000000E-02 |
468 |
ThSI: hiMax = 1.0000000000000E+01 |
469 |
ThSI: hsMax = 1.0000000000000E+01 |
470 |
ThSI: iceMaskMax = 1.0000000000000E+00 |
471 |
ThSI: iceMaskMin = 1.0000000000000E-03 |
472 |
ThSI: fracEnMelt = 4.0000000000000E-01 |
473 |
ThSI: fracEnFreez = 4.0000000000000E-01 |
474 |
ThSI: hThinIce = 2.0000000000000E-01 |
475 |
ThSI: hThickIce = 2.5000000000000E+00 |
476 |
ThSI: hNewIceMax = 1.0000000000000E+00 |
477 |
ThSI: stressReduction = 0.0000000000000E+00 |
478 |
ThSI: thSIce_skipThermo = T |
479 |
ThSI: thSIceAdvScheme = 77 |
480 |
ThSI: thSIceBalanceAtmFW= 0 |
481 |
ThSI: thSIce_diffK = 0.0000000000000E+00 |
482 |
ThSI: thSIce_deltaT = 1.8000000000000E+03 |
483 |
ThSI: ocean_deltaT = 1.8000000000000E+03 |
484 |
ThSI: stepFwd_oceMxL = F |
485 |
ThSI: tauRelax_MxL = 0.0000000000000E+00 |
486 |
ThSI: tauRelax_MxL_salt = 0.0000000000000E+00 |
487 |
ThSI: hMxL_default = 5.0000000000000E+01 |
488 |
ThSI: sMxL_default = 3.5000000000000E+01 |
489 |
ThSI: vMxL_default = 5.0000000000000E-02 |
490 |
ThSI: thSIce_taveFreq = 0.0000000000000E+00 |
491 |
ThSI: thSIce_diagFreq = 4.3200000000000E+05 |
492 |
ThSI: thSIce_monFreq = 1.8000000000000E+03 |
493 |
ThSI: startIceModel = 0 |
494 |
(PID.TID 0000.0001) DIAGNOSTICS_READPARMS: opening data.diagnostics |
495 |
(PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.diagnostics |
496 |
(PID.TID 0000.0001) // ======================================================= |
497 |
(PID.TID 0000.0001) // Parameter file "data.diagnostics" |
498 |
(PID.TID 0000.0001) // ======================================================= |
499 |
(PID.TID 0000.0001) ># Diagnostic Package Choices |
500 |
(PID.TID 0000.0001) >#-------------------- |
501 |
(PID.TID 0000.0001) ># dumpAtLast (logical): always write output at the end of simulation (default=F) |
502 |
(PID.TID 0000.0001) ># diag_mnc (logical): write to NetCDF files (default=useMNC) |
503 |
(PID.TID 0000.0001) >#--for each output-stream: |
504 |
(PID.TID 0000.0001) ># fileName(n) : prefix of the output file name (max 80c long) for outp.stream n |
505 |
(PID.TID 0000.0001) ># frequency(n):< 0 : write snap-shot output every |frequency| seconds |
506 |
(PID.TID 0000.0001) ># > 0 : write time-average output every frequency seconds |
507 |
(PID.TID 0000.0001) ># timePhase(n) : write at time = timePhase + multiple of |frequency| |
508 |
(PID.TID 0000.0001) ># averagingFreq : frequency (in s) for periodic averaging interval |
509 |
(PID.TID 0000.0001) ># averagingPhase : phase (in s) for periodic averaging interval |
510 |
(PID.TID 0000.0001) ># repeatCycle : number of averaging intervals in 1 cycle |
511 |
(PID.TID 0000.0001) ># levels(:,n) : list of levels to write to file (Notes: declared as REAL) |
512 |
(PID.TID 0000.0001) ># when this entry is missing, select all common levels of this list |
513 |
(PID.TID 0000.0001) ># fields(:,n) : list of selected diagnostics fields (8.c) in outp.stream n |
514 |
(PID.TID 0000.0001) ># (see "available_diagnostics.log" file for the full list of diags) |
515 |
(PID.TID 0000.0001) ># missing_value(n) : missing value for real-type fields in output file "n" |
516 |
(PID.TID 0000.0001) ># fileFlags(n) : specific code (8c string) for output file "n" |
517 |
(PID.TID 0000.0001) >#-------------------- |
518 |
(PID.TID 0000.0001) ># This example dumps EXF diagnostics as snapshot after 10 time-steps |
519 |
(PID.TID 0000.0001) ># Note: EXF air-sea fluxes over Sea-Ice are wrong |
520 |
(PID.TID 0000.0001) > &DIAGNOSTICS_LIST |
521 |
(PID.TID 0000.0001) > dumpAtLast = .TRUE., |
522 |
(PID.TID 0000.0001) >#-- |
523 |
(PID.TID 0000.0001) > fields(1:11,1) = 'EXFtaux ','EXFtauy ','EXFqnet ','EXFempmr', |
524 |
(PID.TID 0000.0001) > 'EXFhl ','EXFhs ','EXFswnet','EXFlwnet', |
525 |
(PID.TID 0000.0001) > 'EXFuwind','EXFvwind','EXFatemp', |
526 |
(PID.TID 0000.0001) ># fileName(1) = 'exfDiag', |
527 |
(PID.TID 0000.0001) > frequency(1) = 86400., |
528 |
(PID.TID 0000.0001) > |
529 |
(PID.TID 0000.0001) > fields(1:5,2) = 'SIuice ','SIvice ','SIheff ', |
530 |
(PID.TID 0000.0001) > 'SI_Fract','SI_Thick', |
531 |
(PID.TID 0000.0001) ># fileName(2) = 'iceDiag', |
532 |
(PID.TID 0000.0001) > frequency(2) = 86400., |
533 |
(PID.TID 0000.0001) > missing_value(2) = -999., |
534 |
(PID.TID 0000.0001) > |
535 |
(PID.TID 0000.0001) > fields(1:5,3) = 'SIuice ','SIvice ','SIheff ', |
536 |
(PID.TID 0000.0001) > 'SI_Fract','SI_Thick', |
537 |
(PID.TID 0000.0001) > fileName(3) = 'snapshot', |
538 |
(PID.TID 0000.0001) > frequency(3) = -86400., |
539 |
(PID.TID 0000.0001) > timePhase(3) = 3600., |
540 |
(PID.TID 0000.0001) > missing_value(3) = -999., |
541 |
(PID.TID 0000.0001) > / |
542 |
(PID.TID 0000.0001) > |
543 |
(PID.TID 0000.0001) >#-------------------- |
544 |
(PID.TID 0000.0001) ># Parameter for Diagnostics of per level statistics: |
545 |
(PID.TID 0000.0001) >#-------------------- |
546 |
(PID.TID 0000.0001) ># diagSt_mnc (logical): write stat-diags to NetCDF files (default=diag_mnc) |
547 |
(PID.TID 0000.0001) ># diagSt_regMaskFile : file containing the region-mask to read-in |
548 |
(PID.TID 0000.0001) ># nSetRegMskFile : number of region-mask sets within the region-mask file |
549 |
(PID.TID 0000.0001) ># set_regMask(i) : region-mask set-index that identifies the region "i" |
550 |
(PID.TID 0000.0001) ># val_regMask(i) : region "i" identifier value in the region mask |
551 |
(PID.TID 0000.0001) >#--for each output-stream: |
552 |
(PID.TID 0000.0001) ># stat_fName(n) : prefix of the output file name (max 80c long) for outp.stream n |
553 |
(PID.TID 0000.0001) ># stat_freq(n):< 0 : write snap-shot output every |stat_freq| seconds |
554 |
(PID.TID 0000.0001) ># > 0 : write time-average output every stat_freq seconds |
555 |
(PID.TID 0000.0001) ># stat_phase(n) : write at time = stat_phase + multiple of |stat_freq| |
556 |
(PID.TID 0000.0001) ># stat_region(:,n) : list of "regions" (default: 1 region only=global) |
557 |
(PID.TID 0000.0001) ># stat_fields(:,n) : list of selected diagnostics fields (8.c) in outp.stream n |
558 |
(PID.TID 0000.0001) ># (see "available_diagnostics.log" file for the full list of diags) |
559 |
(PID.TID 0000.0001) >#-------------------- |
560 |
(PID.TID 0000.0001) > &DIAG_STATIS_PARMS |
561 |
(PID.TID 0000.0001) >#stat_fields(1:5,1) = 'SI_Fract','SI_Thick','SI_SnowH', |
562 |
(PID.TID 0000.0001) >#stat_fields(1:5,1) = 'SIarea ','SIheff ','SIhsnow ', |
563 |
(PID.TID 0000.0001) > stat_fields(1:6,1) = 'SI_Fract','SI_Thick', |
564 |
(PID.TID 0000.0001) > 'SIarea ','SIheff ', |
565 |
(PID.TID 0000.0001) > 'SIuice ','SIvice ', |
566 |
(PID.TID 0000.0001) > stat_fName(1) = 'iceStDiag', |
567 |
(PID.TID 0000.0001) > stat_freq(1) = 7200., |
568 |
(PID.TID 0000.0001) > stat_phase(1) = 1800., |
569 |
(PID.TID 0000.0001) > / |
570 |
(PID.TID 0000.0001) |
571 |
(PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "diagnostics_list": start |
572 |
(PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "diagnostics_list": OK |
573 |
(PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "DIAG_STATIS_PARMS": start |
574 |
(PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "DIAG_STATIS_PARMS": OK |
575 |
(PID.TID 0000.0001) DIAGNOSTICS_READPARMS: global parameter summary: |
576 |
(PID.TID 0000.0001) dumpAtLast = /* always write time-ave diags at the end */ |
577 |
(PID.TID 0000.0001) T |
578 |
(PID.TID 0000.0001) ; |
579 |
(PID.TID 0000.0001) diag_mnc = /* write NetCDF output files */ |
580 |
(PID.TID 0000.0001) F |
581 |
(PID.TID 0000.0001) ; |
582 |
(PID.TID 0000.0001) useMissingValue = /* put MissingValue where mask = 0 */ |
583 |
(PID.TID 0000.0001) F |
584 |
(PID.TID 0000.0001) ; |
585 |
(PID.TID 0000.0001) diagCG_maxIters = /* max number of iters in diag_cg2d */ |
586 |
(PID.TID 0000.0001) 500 |
587 |
(PID.TID 0000.0001) ; |
588 |
(PID.TID 0000.0001) diagCG_resTarget = /* residual target for diag_cg2d */ |
589 |
(PID.TID 0000.0001) 1.000000000000000E-12 |
590 |
(PID.TID 0000.0001) ; |
591 |
(PID.TID 0000.0001) diagCG_pcOffDFac = /* preconditioner off-diagonal factor */ |
592 |
(PID.TID 0000.0001) 9.611687812379854E-01 |
593 |
(PID.TID 0000.0001) ; |
594 |
(PID.TID 0000.0001) ----------------------------------------------------- |
595 |
(PID.TID 0000.0001) DIAGNOSTICS_READPARMS: active diagnostics summary: |
596 |
(PID.TID 0000.0001) ----------------------------------------------------- |
597 |
(PID.TID 0000.0001) Creating Output Stream: snapshot |
598 |
(PID.TID 0000.0001) Output Frequency: -86400.000000 ; Phase: 3600.000000 |
599 |
(PID.TID 0000.0001) Averaging Freq.: 0.000000 , Phase: 0.000000 , Cycle: 1 |
600 |
(PID.TID 0000.0001) missing value: -9.990000000000E+02 |
601 |
(PID.TID 0000.0001) Levels: will be set later |
602 |
(PID.TID 0000.0001) Fields: SIuice SIvice SIheff SI_Fract SI_Thick |
603 |
(PID.TID 0000.0001) ----------------------------------------------------- |
604 |
(PID.TID 0000.0001) DIAGNOSTICS_READPARMS: statistics diags. summary: |
605 |
(PID.TID 0000.0001) Creating Stats. Output Stream: iceStDiag |
606 |
(PID.TID 0000.0001) Output Frequency: 7200.000000 ; Phase: 1800.000000 |
607 |
(PID.TID 0000.0001) Regions: 0 |
608 |
(PID.TID 0000.0001) Fields: SI_Fract SI_Thick SIarea SIheff SIuice SIvice |
609 |
(PID.TID 0000.0001) ----------------------------------------------------- |
610 |
(PID.TID 0000.0001) |
611 |
(PID.TID 0000.0001) SET_PARMS: done |
612 |
(PID.TID 0000.0001) Enter INI_VERTICAL_GRID: setInterFDr= T ; setCenterDr= F |
613 |
(PID.TID 0000.0001) %MON XC_max = 3.9750000000000E+05 |
614 |
(PID.TID 0000.0001) %MON XC_min = 2.5000000000000E+03 |
615 |
(PID.TID 0000.0001) %MON XC_mean = 2.0000000000000E+05 |
616 |
(PID.TID 0000.0001) %MON XC_sd = 1.1546103238755E+05 |
617 |
(PID.TID 0000.0001) %MON XG_max = 3.9500000000000E+05 |
618 |
(PID.TID 0000.0001) %MON XG_min = 0.0000000000000E+00 |
619 |
(PID.TID 0000.0001) %MON XG_mean = 1.9750000000000E+05 |
620 |
(PID.TID 0000.0001) %MON XG_sd = 1.1546103238755E+05 |
621 |
(PID.TID 0000.0001) %MON DXC_max = 5.0000000000000E+03 |
622 |
(PID.TID 0000.0001) %MON DXC_min = 5.0000000000000E+03 |
623 |
(PID.TID 0000.0001) %MON DXC_mean = 5.0000000000000E+03 |
624 |
(PID.TID 0000.0001) %MON DXC_sd = 0.0000000000000E+00 |
625 |
(PID.TID 0000.0001) %MON DXF_max = 5.0000000000000E+03 |
626 |
(PID.TID 0000.0001) %MON DXF_min = 5.0000000000000E+03 |
627 |
(PID.TID 0000.0001) %MON DXF_mean = 5.0000000000000E+03 |
628 |
(PID.TID 0000.0001) %MON DXF_sd = 0.0000000000000E+00 |
629 |
(PID.TID 0000.0001) %MON DXG_max = 5.0000000000000E+03 |
630 |
(PID.TID 0000.0001) %MON DXG_min = 5.0000000000000E+03 |
631 |
(PID.TID 0000.0001) %MON DXG_mean = 5.0000000000000E+03 |
632 |
(PID.TID 0000.0001) %MON DXG_sd = 0.0000000000000E+00 |
633 |
(PID.TID 0000.0001) %MON DXV_max = 5.0000000000000E+03 |
634 |
(PID.TID 0000.0001) %MON DXV_min = 5.0000000000000E+03 |
635 |
(PID.TID 0000.0001) %MON DXV_mean = 5.0000000000000E+03 |
636 |
(PID.TID 0000.0001) %MON DXV_sd = 0.0000000000000E+00 |
637 |
(PID.TID 0000.0001) %MON YC_max = 9.7500000000000E+04 |
638 |
(PID.TID 0000.0001) %MON YC_min = -1.0750000000000E+05 |
639 |
(PID.TID 0000.0001) %MON YC_mean = -5.0000000000000E+03 |
640 |
(PID.TID 0000.0001) %MON YC_sd = 6.0604592785256E+04 |
641 |
(PID.TID 0000.0001) %MON YG_max = 9.5000000000000E+04 |
642 |
(PID.TID 0000.0001) %MON YG_min = -1.1000000000000E+05 |
643 |
(PID.TID 0000.0001) %MON YG_mean = -7.5000000000000E+03 |
644 |
(PID.TID 0000.0001) %MON YG_sd = 6.0604592785256E+04 |
645 |
(PID.TID 0000.0001) %MON DYC_max = 5.0000000000000E+03 |
646 |
(PID.TID 0000.0001) %MON DYC_min = 5.0000000000000E+03 |
647 |
(PID.TID 0000.0001) %MON DYC_mean = 5.0000000000000E+03 |
648 |
(PID.TID 0000.0001) %MON DYC_sd = 0.0000000000000E+00 |
649 |
(PID.TID 0000.0001) %MON DYF_max = 5.0000000000000E+03 |
650 |
(PID.TID 0000.0001) %MON DYF_min = 5.0000000000000E+03 |
651 |
(PID.TID 0000.0001) %MON DYF_mean = 5.0000000000000E+03 |
652 |
(PID.TID 0000.0001) %MON DYF_sd = 0.0000000000000E+00 |
653 |
(PID.TID 0000.0001) %MON DYG_max = 5.0000000000000E+03 |
654 |
(PID.TID 0000.0001) %MON DYG_min = 5.0000000000000E+03 |
655 |
(PID.TID 0000.0001) %MON DYG_mean = 5.0000000000000E+03 |
656 |
(PID.TID 0000.0001) %MON DYG_sd = 0.0000000000000E+00 |
657 |
(PID.TID 0000.0001) %MON DYU_max = 5.0000000000000E+03 |
658 |
(PID.TID 0000.0001) %MON DYU_min = 5.0000000000000E+03 |
659 |
(PID.TID 0000.0001) %MON DYU_mean = 5.0000000000000E+03 |
660 |
(PID.TID 0000.0001) %MON DYU_sd = 0.0000000000000E+00 |
661 |
(PID.TID 0000.0001) %MON RA_max = 2.5000000000000E+07 |
662 |
(PID.TID 0000.0001) %MON RA_min = 2.5000000000000E+07 |
663 |
(PID.TID 0000.0001) %MON RA_mean = 2.5000000000000E+07 |
664 |
(PID.TID 0000.0001) %MON RA_sd = 3.7252902984619E-09 |
665 |
(PID.TID 0000.0001) %MON RAW_max = 2.5000000000000E+07 |
666 |
(PID.TID 0000.0001) %MON RAW_min = 2.5000000000000E+07 |
667 |
(PID.TID 0000.0001) %MON RAW_mean = 2.5000000000000E+07 |
668 |
(PID.TID 0000.0001) %MON RAW_sd = 3.7252902984619E-09 |
669 |
(PID.TID 0000.0001) %MON RAS_max = 2.5000000000000E+07 |
670 |
(PID.TID 0000.0001) %MON RAS_min = 2.5000000000000E+07 |
671 |
(PID.TID 0000.0001) %MON RAS_mean = 2.5000000000000E+07 |
672 |
(PID.TID 0000.0001) %MON RAS_sd = 3.7252902984619E-09 |
673 |
(PID.TID 0000.0001) %MON RAZ_max = 2.5000000000000E+07 |
674 |
(PID.TID 0000.0001) %MON RAZ_min = 2.5000000000000E+07 |
675 |
(PID.TID 0000.0001) %MON RAZ_mean = 2.5000000000000E+07 |
676 |
(PID.TID 0000.0001) %MON RAZ_sd = 3.7252902984619E-09 |
677 |
(PID.TID 0000.0001) %MON AngleCS_max = 1.0000000000000E+00 |
678 |
(PID.TID 0000.0001) %MON AngleCS_min = 1.0000000000000E+00 |
679 |
(PID.TID 0000.0001) %MON AngleCS_mean = 1.0000000000000E+00 |
680 |
(PID.TID 0000.0001) %MON AngleCS_sd = 0.0000000000000E+00 |
681 |
(PID.TID 0000.0001) %MON AngleSN_max = 0.0000000000000E+00 |
682 |
(PID.TID 0000.0001) %MON AngleSN_min = 0.0000000000000E+00 |
683 |
(PID.TID 0000.0001) %MON AngleSN_mean = 0.0000000000000E+00 |
684 |
(PID.TID 0000.0001) %MON AngleSN_sd = 0.0000000000000E+00 |
685 |
(PID.TID 0000.0001) MDS_READ_FIELD: opening global file: bathy_3c.bin |
686 |
(PID.TID 0000.0001) // ======================================================= |
687 |
(PID.TID 0000.0001) // Field Model R_low (ini_masks_etc) |
688 |
(PID.TID 0000.0001) // CMIN = -1.000000000000000E+01 |
689 |
(PID.TID 0000.0001) // CMAX = -1.000000000000000E+01 |
690 |
(PID.TID 0000.0001) // CINT = 0.000000000000000E+00 |
691 |
(PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+ |
692 |
(PID.TID 0000.0001) // 0.0: . |
693 |
(PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):( -2: 83: 1) |
694 |
(PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):( 45: -2: -1) |
695 |
(PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):( 1: 1: 1) |
696 |
(PID.TID 0000.0001) // ======================================================= |
697 |
(PID.TID 0000.0001) // ======================================================= |
698 |
(PID.TID 0000.0001) // END OF FIELD = |
699 |
(PID.TID 0000.0001) // ======================================================= |
700 |
(PID.TID 0000.0001) |
701 |
(PID.TID 0000.0001) // ======================================================= |
702 |
(PID.TID 0000.0001) // Field Model Ro_surf (ini_masks_etc) |
703 |
(PID.TID 0000.0001) // CMIN = 1.000000000000000E+32 |
704 |
(PID.TID 0000.0001) // CMAX = -1.000000000000000E+32 |
705 |
(PID.TID 0000.0001) // CINT = 0.000000000000000E+00 |
706 |
(PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+ |
707 |
(PID.TID 0000.0001) // 0.0: . |
708 |
(PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):( -2: 83: 1) |
709 |
(PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):( 45: -2: -1) |
710 |
(PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):( 1: 1: 1) |
711 |
(PID.TID 0000.0001) // ======================================================= |
712 |
(PID.TID 0000.0001) // ======================================================= |
713 |
(PID.TID 0000.0001) // END OF FIELD = |
714 |
(PID.TID 0000.0001) // ======================================================= |
715 |
(PID.TID 0000.0001) |
716 |
(PID.TID 0000.0001) // ======================================================= |
717 |
(PID.TID 0000.0001) // Field hFacC at iteration 0 |
718 |
(PID.TID 0000.0001) // CMIN = 1.000000000000000E+00 |
719 |
(PID.TID 0000.0001) // CMAX = 1.000000000000000E+00 |
720 |
(PID.TID 0000.0001) // CINT = 0.000000000000000E+00 |
721 |
(PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+ |
722 |
(PID.TID 0000.0001) // 0.0: . |
723 |
(PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):( -2: 83: 1) |
724 |
(PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):( 45: -2: -1) |
725 |
(PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):( 1: 1: 1) |
726 |
(PID.TID 0000.0001) // ======================================================= |
727 |
(PID.TID 0000.0001) // ======================================================= |
728 |
(PID.TID 0000.0001) // END OF FIELD = |
729 |
(PID.TID 0000.0001) // ======================================================= |
730 |
(PID.TID 0000.0001) |
731 |
(PID.TID 0000.0001) // ======================================================= |
732 |
(PID.TID 0000.0001) // Field hFacW at iteration 0 |
733 |
(PID.TID 0000.0001) // CMIN = 1.000000000000000E+00 |
734 |
(PID.TID 0000.0001) // CMAX = 1.000000000000000E+00 |
735 |
(PID.TID 0000.0001) // CINT = 0.000000000000000E+00 |
736 |
(PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+ |
737 |
(PID.TID 0000.0001) // 0.0: . |
738 |
(PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):( -2: 83: 1) |
739 |
(PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):( 45: -2: -1) |
740 |
(PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):( 1: 1: 1) |
741 |
(PID.TID 0000.0001) // ======================================================= |
742 |
(PID.TID 0000.0001) // ======================================================= |
743 |
(PID.TID 0000.0001) // END OF FIELD = |
744 |
(PID.TID 0000.0001) // ======================================================= |
745 |
(PID.TID 0000.0001) |
746 |
(PID.TID 0000.0001) // ======================================================= |
747 |
(PID.TID 0000.0001) // Field hFacS at iteration 0 |
748 |
(PID.TID 0000.0001) // CMIN = 1.000000000000000E+00 |
749 |
(PID.TID 0000.0001) // CMAX = 1.000000000000000E+00 |
750 |
(PID.TID 0000.0001) // CINT = 0.000000000000000E+00 |
751 |
(PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+ |
752 |
(PID.TID 0000.0001) // 0.0: . |
753 |
(PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):( -2: 83: 1) |
754 |
(PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):( 45: -2: -1) |
755 |
(PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):( 1: 1: 1) |
756 |
(PID.TID 0000.0001) // ======================================================= |
757 |
(PID.TID 0000.0001) // ======================================================= |
758 |
(PID.TID 0000.0001) // END OF FIELD = |
759 |
(PID.TID 0000.0001) // ======================================================= |
760 |
(PID.TID 0000.0001) |
761 |
(PID.TID 0000.0001) |
762 |
(PID.TID 0000.0001) // ======================================================= |
763 |
(PID.TID 0000.0001) // Calendar configuration >>> START <<< |
764 |
(PID.TID 0000.0001) // ======================================================= |
765 |
(PID.TID 0000.0001) |
766 |
(PID.TID 0000.0001) modelstart = /* Start time of the model integration [s] */ |
767 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
768 |
(PID.TID 0000.0001) ; |
769 |
(PID.TID 0000.0001) modelend = /* End time of the model integration [s] */ |
770 |
(PID.TID 0000.0001) 2.160000000000000E+04 |
771 |
(PID.TID 0000.0001) ; |
772 |
(PID.TID 0000.0001) modelStep = /* Time interval for a model forward step [s] */ |
773 |
(PID.TID 0000.0001) 1.800000000000000E+03 |
774 |
(PID.TID 0000.0001) ; |
775 |
(PID.TID 0000.0001) usingGregorianCalendar= /* Calendar Type: Gregorian Calendar */ |
776 |
(PID.TID 0000.0001) T |
777 |
(PID.TID 0000.0001) ; |
778 |
(PID.TID 0000.0001) usingJulianCalendar = /* Calendar Type: Julian Calendar */ |
779 |
(PID.TID 0000.0001) F |
780 |
(PID.TID 0000.0001) ; |
781 |
(PID.TID 0000.0001) usingNoLeapYearCal = /* Calendar Type: without Leap Year */ |
782 |
(PID.TID 0000.0001) F |
783 |
(PID.TID 0000.0001) ; |
784 |
(PID.TID 0000.0001) usingModelCalendar = /* Calendar Type: Model Calendar */ |
785 |
(PID.TID 0000.0001) F |
786 |
(PID.TID 0000.0001) ; |
787 |
(PID.TID 0000.0001) modelStartDate YYYYMMDD = /* Model start date YYYY-MM-DD */ |
788 |
(PID.TID 0000.0001) 19790101 |
789 |
(PID.TID 0000.0001) ; |
790 |
(PID.TID 0000.0001) modelStartDate HHMMSS = /* Model start date HH-MM-SS */ |
791 |
(PID.TID 0000.0001) 0 |
792 |
(PID.TID 0000.0001) ; |
793 |
(PID.TID 0000.0001) modelEndDate YYYYMMDD = /* Model end date YYYY-MM-DD */ |
794 |
(PID.TID 0000.0001) 19790101 |
795 |
(PID.TID 0000.0001) ; |
796 |
(PID.TID 0000.0001) modelEndDate HHMMSS = /* Model end date HH-MM-SS */ |
797 |
(PID.TID 0000.0001) 60000 |
798 |
(PID.TID 0000.0001) ; |
799 |
(PID.TID 0000.0001) intyears = /* Number of calendar years affected by the integration */ |
800 |
(PID.TID 0000.0001) 1 |
801 |
(PID.TID 0000.0001) ; |
802 |
(PID.TID 0000.0001) intmonths= /* Number of calendar months affected by the integration */ |
803 |
(PID.TID 0000.0001) 1 |
804 |
(PID.TID 0000.0001) ; |
805 |
(PID.TID 0000.0001) intdays = /* Number of calendar days affected by the integration */ |
806 |
(PID.TID 0000.0001) 1 |
807 |
(PID.TID 0000.0001) ; |
808 |
(PID.TID 0000.0001) modelIter0 = /* Base timestep number */ |
809 |
(PID.TID 0000.0001) 0 |
810 |
(PID.TID 0000.0001) ; |
811 |
(PID.TID 0000.0001) modelIterEnd = /* Final timestep number */ |
812 |
(PID.TID 0000.0001) 12 |
813 |
(PID.TID 0000.0001) ; |
814 |
(PID.TID 0000.0001) modelIntSteps= /* Number of model timesteps */ |
815 |
(PID.TID 0000.0001) 12 |
816 |
(PID.TID 0000.0001) ; |
817 |
(PID.TID 0000.0001) |
818 |
(PID.TID 0000.0001) // ======================================================= |
819 |
(PID.TID 0000.0001) // Calendar configuration >>> END <<< |
820 |
(PID.TID 0000.0001) // ======================================================= |
821 |
(PID.TID 0000.0001) |
822 |
(PID.TID 0000.0001) GAD_INIT_FIXED: GAD_OlMinSize= 0 0 1 |
823 |
(PID.TID 0000.0001) |
824 |
(PID.TID 0000.0001) // =================================== |
825 |
(PID.TID 0000.0001) // GAD parameters : |
826 |
(PID.TID 0000.0001) // =================================== |
827 |
(PID.TID 0000.0001) tempAdvScheme = /* Temp. Horiz.Advection scheme selector */ |
828 |
(PID.TID 0000.0001) 2 |
829 |
(PID.TID 0000.0001) ; |
830 |
(PID.TID 0000.0001) tempVertAdvScheme = /* Temp. Vert. Advection scheme selector */ |
831 |
(PID.TID 0000.0001) 2 |
832 |
(PID.TID 0000.0001) ; |
833 |
(PID.TID 0000.0001) tempMultiDimAdvec = /* use Muti-Dim Advec method for Temp */ |
834 |
(PID.TID 0000.0001) F |
835 |
(PID.TID 0000.0001) ; |
836 |
(PID.TID 0000.0001) tempSOM_Advection = /* use 2nd Order Moment Advection for Temp */ |
837 |
(PID.TID 0000.0001) F |
838 |
(PID.TID 0000.0001) ; |
839 |
(PID.TID 0000.0001) AdamsBashforthGt = /* apply Adams-Bashforth extrapolation on Gt */ |
840 |
(PID.TID 0000.0001) F |
841 |
(PID.TID 0000.0001) ; |
842 |
(PID.TID 0000.0001) AdamsBashforth_T = /* apply Adams-Bashforth extrapolation on Temp */ |
843 |
(PID.TID 0000.0001) F |
844 |
(PID.TID 0000.0001) ; |
845 |
(PID.TID 0000.0001) saltAdvScheme = /* Salt. Horiz.advection scheme selector */ |
846 |
(PID.TID 0000.0001) 2 |
847 |
(PID.TID 0000.0001) ; |
848 |
(PID.TID 0000.0001) saltVertAdvScheme = /* Salt. Vert. Advection scheme selector */ |
849 |
(PID.TID 0000.0001) 2 |
850 |
(PID.TID 0000.0001) ; |
851 |
(PID.TID 0000.0001) saltMultiDimAdvec = /* use Muti-Dim Advec method for Salt */ |
852 |
(PID.TID 0000.0001) F |
853 |
(PID.TID 0000.0001) ; |
854 |
(PID.TID 0000.0001) saltSOM_Advection = /* use 2nd Order Moment Advection for Salt */ |
855 |
(PID.TID 0000.0001) F |
856 |
(PID.TID 0000.0001) ; |
857 |
(PID.TID 0000.0001) AdamsBashforthGs = /* apply Adams-Bashforth extrapolation on Gs */ |
858 |
(PID.TID 0000.0001) F |
859 |
(PID.TID 0000.0001) ; |
860 |
(PID.TID 0000.0001) AdamsBashforth_S = /* apply Adams-Bashforth extrapolation on Salt */ |
861 |
(PID.TID 0000.0001) F |
862 |
(PID.TID 0000.0001) ; |
863 |
(PID.TID 0000.0001) // =================================== |
864 |
(PID.TID 0000.0001) |
865 |
(PID.TID 0000.0001) // ======================================================= |
866 |
(PID.TID 0000.0001) // External forcing (EXF) configuration >>> START <<< |
867 |
(PID.TID 0000.0001) // ======================================================= |
868 |
(PID.TID 0000.0001) |
869 |
(PID.TID 0000.0001) EXF general parameters: |
870 |
(PID.TID 0000.0001) |
871 |
(PID.TID 0000.0001) exf_iprec = /* exf file precision */ |
872 |
(PID.TID 0000.0001) 64 |
873 |
(PID.TID 0000.0001) ; |
874 |
(PID.TID 0000.0001) useExfYearlyFields = /* add extension _YEAR to input file names */ |
875 |
(PID.TID 0000.0001) F |
876 |
(PID.TID 0000.0001) ; |
877 |
(PID.TID 0000.0001) twoDigitYear = /* use 2-digit year extension */ |
878 |
(PID.TID 0000.0001) F |
879 |
(PID.TID 0000.0001) ; |
880 |
(PID.TID 0000.0001) useExfCheckRange = /* check for fields range */ |
881 |
(PID.TID 0000.0001) T |
882 |
(PID.TID 0000.0001) ; |
883 |
(PID.TID 0000.0001) exf_debugLev = /* select EXF-debug printing level */ |
884 |
(PID.TID 0000.0001) 2 |
885 |
(PID.TID 0000.0001) ; |
886 |
(PID.TID 0000.0001) exf_monFreq = /* EXF monitor frequency [ s ] */ |
887 |
(PID.TID 0000.0001) 8.640000000000000E+07 |
888 |
(PID.TID 0000.0001) ; |
889 |
(PID.TID 0000.0001) repeatPeriod = /* period for cycling forcing dataset [ s ] */ |
890 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
891 |
(PID.TID 0000.0001) ; |
892 |
(PID.TID 0000.0001) climTempFreeze= /* Minimum climatological temperature [deg.C] */ |
893 |
(PID.TID 0000.0001) -1.900000000000000E+00 |
894 |
(PID.TID 0000.0001) ; |
895 |
(PID.TID 0000.0001) windStressMax = /* Maximum absolute windstress [ Pa ] */ |
896 |
(PID.TID 0000.0001) 2.000000000000000E+00 |
897 |
(PID.TID 0000.0001) ; |
898 |
(PID.TID 0000.0001) stressIsOnCgrid = /* set u,v_stress on Arakawa C-grid */ |
899 |
(PID.TID 0000.0001) F |
900 |
(PID.TID 0000.0001) ; |
901 |
(PID.TID 0000.0001) cen2kel = /* conversion of deg. Centigrade to Kelvin [K] */ |
902 |
(PID.TID 0000.0001) 2.731500000000000E+02 |
903 |
(PID.TID 0000.0001) ; |
904 |
(PID.TID 0000.0001) gravity_mks= /* gravitational acceleration [m/s^2] */ |
905 |
(PID.TID 0000.0001) 9.810000000000000E+00 |
906 |
(PID.TID 0000.0001) ; |
907 |
(PID.TID 0000.0001) atmrho = /* mean atmospheric density [kg/m^3] */ |
908 |
(PID.TID 0000.0001) 1.200000000000000E+00 |
909 |
(PID.TID 0000.0001) ; |
910 |
(PID.TID 0000.0001) atmcp = /* mean atmospheric specific heat [J/kg/K] */ |
911 |
(PID.TID 0000.0001) 1.005000000000000E+03 |
912 |
(PID.TID 0000.0001) ; |
913 |
(PID.TID 0000.0001) flamb = /* latent heat of evaporation [J/kg] */ |
914 |
(PID.TID 0000.0001) 2.500000000000000E+06 |
915 |
(PID.TID 0000.0001) ; |
916 |
(PID.TID 0000.0001) flami = /* latent heat of pure-ice melting [J/kg] */ |
917 |
(PID.TID 0000.0001) 3.340000000000000E+05 |
918 |
(PID.TID 0000.0001) ; |
919 |
(PID.TID 0000.0001) cvapor_fac = /* const. for Saturation calculation [?] */ |
920 |
(PID.TID 0000.0001) 6.403800000000000E+05 |
921 |
(PID.TID 0000.0001) ; |
922 |
(PID.TID 0000.0001) cvapor_exp = /* const. for Saturation calculation [?] */ |
923 |
(PID.TID 0000.0001) 5.107400000000000E+03 |
924 |
(PID.TID 0000.0001) ; |
925 |
(PID.TID 0000.0001) cvapor_fac_ice= /* const. for Saturation calculation [?] */ |
926 |
(PID.TID 0000.0001) 1.163780000000000E+07 |
927 |
(PID.TID 0000.0001) ; |
928 |
(PID.TID 0000.0001) cvapor_exp_ice= /* const. for Saturation calculation [?] */ |
929 |
(PID.TID 0000.0001) 5.897800000000000E+03 |
930 |
(PID.TID 0000.0001) ; |
931 |
(PID.TID 0000.0001) humid_fac = /* humidity coef. in virtual temp. [(kg/kg)^-1] */ |
932 |
(PID.TID 0000.0001) 6.060000000000000E-01 |
933 |
(PID.TID 0000.0001) ; |
934 |
(PID.TID 0000.0001) gamma_blk = /* adiabatic lapse rate [?] */ |
935 |
(PID.TID 0000.0001) 1.000000000000000E-02 |
936 |
(PID.TID 0000.0001) ; |
937 |
(PID.TID 0000.0001) saltsat = /* reduction of Qsat over salty water [-] */ |
938 |
(PID.TID 0000.0001) 9.800000000000000E-01 |
939 |
(PID.TID 0000.0001) ; |
940 |
(PID.TID 0000.0001) noNegativeEvap = /* prevent negative Evaporation */ |
941 |
(PID.TID 0000.0001) F |
942 |
(PID.TID 0000.0001) ; |
943 |
(PID.TID 0000.0001) sstExtrapol = /* extrapolation coeff from lev. 1 & 2 to surf [-] */ |
944 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
945 |
(PID.TID 0000.0001) ; |
946 |
(PID.TID 0000.0001) cDrag_1 = /* coef used in drag calculation [?] */ |
947 |
(PID.TID 0000.0001) 2.700000000000000E-03 |
948 |
(PID.TID 0000.0001) ; |
949 |
(PID.TID 0000.0001) cDrag_2 = /* coef used in drag calculation [?] */ |
950 |
(PID.TID 0000.0001) 1.420000000000000E-04 |
951 |
(PID.TID 0000.0001) ; |
952 |
(PID.TID 0000.0001) cDrag_3 = /* coef used in drag calculation [?] */ |
953 |
(PID.TID 0000.0001) 7.640000000000000E-05 |
954 |
(PID.TID 0000.0001) ; |
955 |
(PID.TID 0000.0001) cStanton_1 = /* coef used in Stanton number calculation [?] */ |
956 |
(PID.TID 0000.0001) 3.270000000000000E-02 |
957 |
(PID.TID 0000.0001) ; |
958 |
(PID.TID 0000.0001) cStanton_2 = /* coef used in Stanton number calculation [?] */ |
959 |
(PID.TID 0000.0001) 1.800000000000000E-02 |
960 |
(PID.TID 0000.0001) ; |
961 |
(PID.TID 0000.0001) cDalton = /* coef used in Dalton number calculation [?] */ |
962 |
(PID.TID 0000.0001) 3.460000000000000E-02 |
963 |
(PID.TID 0000.0001) ; |
964 |
(PID.TID 0000.0001) exf_scal_BulkCdn= /* Drag coefficient scaling factor [-] */ |
965 |
(PID.TID 0000.0001) 1.000000000000000E+00 |
966 |
(PID.TID 0000.0001) ; |
967 |
(PID.TID 0000.0001) zolmin = /* minimum stability parameter [?] */ |
968 |
(PID.TID 0000.0001) -1.000000000000000E+02 |
969 |
(PID.TID 0000.0001) ; |
970 |
(PID.TID 0000.0001) psim_fac = /* coef used in turbulent fluxes calculation [-] */ |
971 |
(PID.TID 0000.0001) 5.000000000000000E+00 |
972 |
(PID.TID 0000.0001) ; |
973 |
(PID.TID 0000.0001) zref = /* reference height [ m ] */ |
974 |
(PID.TID 0000.0001) 1.000000000000000E+01 |
975 |
(PID.TID 0000.0001) ; |
976 |
(PID.TID 0000.0001) hu = /* height of mean wind [ m ] */ |
977 |
(PID.TID 0000.0001) 1.000000000000000E+01 |
978 |
(PID.TID 0000.0001) ; |
979 |
(PID.TID 0000.0001) ht = /* height of mean temperature [ m ] */ |
980 |
(PID.TID 0000.0001) 2.000000000000000E+00 |
981 |
(PID.TID 0000.0001) ; |
982 |
(PID.TID 0000.0001) hq = /* height of mean spec.humidity [ m ] */ |
983 |
(PID.TID 0000.0001) 2.000000000000000E+00 |
984 |
(PID.TID 0000.0001) ; |
985 |
(PID.TID 0000.0001) uMin = /* minimum wind speed [m/s] */ |
986 |
(PID.TID 0000.0001) 5.000000000000000E-01 |
987 |
(PID.TID 0000.0001) ; |
988 |
(PID.TID 0000.0001) useStabilityFct_overIce= /* transfert Coeffs over sea-ice depend on stability */ |
989 |
(PID.TID 0000.0001) F |
990 |
(PID.TID 0000.0001) ; |
991 |
(PID.TID 0000.0001) exf_iceCd = /* drag coefficient over sea-ice (fixed) [-] */ |
992 |
(PID.TID 0000.0001) 1.630000000000000E-03 |
993 |
(PID.TID 0000.0001) ; |
994 |
(PID.TID 0000.0001) exf_iceCe = /* transfert coeff. over sea-ice, for Evap (fixed) [-] */ |
995 |
(PID.TID 0000.0001) 1.630000000000000E-03 |
996 |
(PID.TID 0000.0001) ; |
997 |
(PID.TID 0000.0001) exf_iceCh = /* transfert coeff. over sea-ice, Sens.Heat.(fixed)[-] */ |
998 |
(PID.TID 0000.0001) 1.630000000000000E-03 |
999 |
(PID.TID 0000.0001) ; |
1000 |
(PID.TID 0000.0001) exf_albedo = /* Sea-water albedo [-] */ |
1001 |
(PID.TID 0000.0001) 1.000000000000000E-01 |
1002 |
(PID.TID 0000.0001) ; |
1003 |
(PID.TID 0000.0001) useExfZenAlbedo = /* Sea-water albedo varies with zenith angle */ |
1004 |
(PID.TID 0000.0001) F |
1005 |
(PID.TID 0000.0001) ; |
1006 |
(PID.TID 0000.0001) select_ZenAlbedo = /* Sea-water albedo computation method */ |
1007 |
(PID.TID 0000.0001) 0 |
1008 |
(PID.TID 0000.0001) ; |
1009 |
(PID.TID 0000.0001) useExfZenIncoming = /* compute incoming solar radiation */ |
1010 |
(PID.TID 0000.0001) F |
1011 |
(PID.TID 0000.0001) ; |
1012 |
(PID.TID 0000.0001) ocean_emissivity = /* longwave ocean-surface emissivity [-] */ |
1013 |
(PID.TID 0000.0001) 9.700176366843034E-01 |
1014 |
(PID.TID 0000.0001) ; |
1015 |
(PID.TID 0000.0001) ice_emissivity = /* longwave seaice emissivity [-] */ |
1016 |
(PID.TID 0000.0001) 9.500000000000000E-01 |
1017 |
(PID.TID 0000.0001) ; |
1018 |
(PID.TID 0000.0001) snow_emissivity = /* longwave snow emissivity [-] */ |
1019 |
(PID.TID 0000.0001) 9.500000000000000E-01 |
1020 |
(PID.TID 0000.0001) ; |
1021 |
(PID.TID 0000.0001) |
1022 |
(PID.TID 0000.0001) EXF main CPP flags: |
1023 |
(PID.TID 0000.0001) |
1024 |
(PID.TID 0000.0001) // USE_EXF_INTERPOLATION: NOT defined |
1025 |
(PID.TID 0000.0001) // ALLOW_ATM_TEMP: defined |
1026 |
(PID.TID 0000.0001) // ALLOW_ATM_WIND (useAtmWind): defined |
1027 |
(PID.TID 0000.0001) // ALLOW_DOWNWARD_RADIATION: defined |
1028 |
(PID.TID 0000.0001) // ALLOW_BULKFORMULAE: defined |
1029 |
(PID.TID 0000.0001) |
1030 |
(PID.TID 0000.0001) Net shortwave flux forcing starts at 0. |
1031 |
(PID.TID 0000.0001) Net shortwave flux forcing period is 0. |
1032 |
(PID.TID 0000.0001) Net shortwave flux forcing is read from file: |
1033 |
(PID.TID 0000.0001) >> << |
1034 |
(PID.TID 0000.0001) |
1035 |
(PID.TID 0000.0001) Zonal wind forcing starts at 0. |
1036 |
(PID.TID 0000.0001) Zonal wind forcing period is 0. |
1037 |
(PID.TID 0000.0001) Zonal wind forcing is read from file: |
1038 |
(PID.TID 0000.0001) >> windx.bin << |
1039 |
(PID.TID 0000.0001) |
1040 |
(PID.TID 0000.0001) Meridional wind forcing starts at 0. |
1041 |
(PID.TID 0000.0001) Meridional wind forcing period is 0. |
1042 |
(PID.TID 0000.0001) Meridional wind forcing is read from file: |
1043 |
(PID.TID 0000.0001) >> << |
1044 |
(PID.TID 0000.0001) |
1045 |
(PID.TID 0000.0001) Atmospheric temperature starts at 0. |
1046 |
(PID.TID 0000.0001) Atmospheric temperature period is 0. |
1047 |
(PID.TID 0000.0001) Atmospheric temperature is read from file: |
1048 |
(PID.TID 0000.0001) >> << |
1049 |
(PID.TID 0000.0001) |
1050 |
(PID.TID 0000.0001) Atmospheric specific humidity starts at 0. |
1051 |
(PID.TID 0000.0001) Atmospheric specific humidity period is 0. |
1052 |
(PID.TID 0000.0001) Atmospheric specific humidity is read from file: |
1053 |
(PID.TID 0000.0001) >> << |
1054 |
(PID.TID 0000.0001) |
1055 |
(PID.TID 0000.0001) Net longwave flux forcing starts at 0. |
1056 |
(PID.TID 0000.0001) Net longwave flux forcing period is 0. |
1057 |
(PID.TID 0000.0001) Net longwave flux forcing is read from file: |
1058 |
(PID.TID 0000.0001) >> << |
1059 |
(PID.TID 0000.0001) |
1060 |
(PID.TID 0000.0001) Precipitation data set starts at 0. |
1061 |
(PID.TID 0000.0001) Precipitation data period is 0. |
1062 |
(PID.TID 0000.0001) Precipitation data is read from file: |
1063 |
(PID.TID 0000.0001) >> << |
1064 |
(PID.TID 0000.0001) |
1065 |
(PID.TID 0000.0001) // EXF_READ_EVAP: NOT defined |
1066 |
(PID.TID 0000.0001) |
1067 |
(PID.TID 0000.0001) // ALLOW_RUNOFF: defined |
1068 |
(PID.TID 0000.0001) Runoff starts at 0. |
1069 |
(PID.TID 0000.0001) Runoff period is 0. |
1070 |
(PID.TID 0000.0001) Runoff is read from file: |
1071 |
(PID.TID 0000.0001) >> << |
1072 |
(PID.TID 0000.0001) // ALLOW_RUNOFTEMP: NOT defined |
1073 |
(PID.TID 0000.0001) |
1074 |
(PID.TID 0000.0001) Downward shortwave flux forcing starts at 0. |
1075 |
(PID.TID 0000.0001) Downward shortwave flux forcing period is 0. |
1076 |
(PID.TID 0000.0001) Downward shortwave flux forcing is read from file: |
1077 |
(PID.TID 0000.0001) >> << |
1078 |
(PID.TID 0000.0001) |
1079 |
(PID.TID 0000.0001) Downward longwave flux forcing starts at 0. |
1080 |
(PID.TID 0000.0001) Downward longwave flux forcing period is 0. |
1081 |
(PID.TID 0000.0001) Downward longwave flux forcing is read from file: |
1082 |
(PID.TID 0000.0001) >> << |
1083 |
(PID.TID 0000.0001) |
1084 |
(PID.TID 0000.0001) Atmospheric pressure forcing starts at 0. |
1085 |
(PID.TID 0000.0001) Atmospheric pressure forcing period is 0. |
1086 |
(PID.TID 0000.0001) Atmospheric pressureforcing is read from file: |
1087 |
(PID.TID 0000.0001) >> << |
1088 |
(PID.TID 0000.0001) |
1089 |
(PID.TID 0000.0001) // ======================================================= |
1090 |
(PID.TID 0000.0001) // External forcing (EXF) climatology configuration : |
1091 |
(PID.TID 0000.0001) // ======================================================= |
1092 |
(PID.TID 0000.0001) |
1093 |
(PID.TID 0000.0001) // ALLOW_CLIMSST_RELAXATION: defined |
1094 |
(PID.TID 0000.0001) // ALLOW_CLIMSSS_RELAXATION: defined |
1095 |
(PID.TID 0000.0001) |
1096 |
(PID.TID 0000.0001) Climatological SST starts at 0. |
1097 |
(PID.TID 0000.0001) Climatological SST period is 0. |
1098 |
(PID.TID 0000.0001) Climatological SST is read from file: |
1099 |
(PID.TID 0000.0001) >> << |
1100 |
(PID.TID 0000.0001) |
1101 |
(PID.TID 0000.0001) Climatological SSS starts at 0. |
1102 |
(PID.TID 0000.0001) Climatological SSS period is 0. |
1103 |
(PID.TID 0000.0001) Climatological SSS is read from file: |
1104 |
(PID.TID 0000.0001) >> << |
1105 |
(PID.TID 0000.0001) |
1106 |
(PID.TID 0000.0001) // ======================================================= |
1107 |
(PID.TID 0000.0001) // External forcing (EXF) configuration >>> END <<< |
1108 |
(PID.TID 0000.0001) // ======================================================= |
1109 |
(PID.TID 0000.0001) |
1110 |
(PID.TID 0000.0001) // ======================================================= |
1111 |
(PID.TID 0000.0001) // Seaice configuration (SEAICE_PARM01) >>> START <<< |
1112 |
(PID.TID 0000.0001) // ======================================================= |
1113 |
(PID.TID 0000.0001) |
1114 |
(PID.TID 0000.0001) Seaice time stepping configuration > START < |
1115 |
(PID.TID 0000.0001) ---------------------------------------------- |
1116 |
(PID.TID 0000.0001) SEAICE_deltaTtherm= /* thermodynamic timestep */ |
1117 |
(PID.TID 0000.0001) 1.800000000000000E+03 |
1118 |
(PID.TID 0000.0001) ; |
1119 |
(PID.TID 0000.0001) SEAICE_deltaTdyn = /* dynamic timestep */ |
1120 |
(PID.TID 0000.0001) 1.800000000000000E+03 |
1121 |
(PID.TID 0000.0001) ; |
1122 |
(PID.TID 0000.0001) SEAICE_deltaTevp = /* EVP timestep */ |
1123 |
(PID.TID 0000.0001) 1.234567000000000E+05 |
1124 |
(PID.TID 0000.0001) ; |
1125 |
(PID.TID 0000.0001) SEAICEuseBDF2 = /* use backw. differencing for mom. eq. */ |
1126 |
(PID.TID 0000.0001) F |
1127 |
(PID.TID 0000.0001) ; |
1128 |
(PID.TID 0000.0001) SEAICErestoreUnderIce = /* restore T and S under ice */ |
1129 |
(PID.TID 0000.0001) F |
1130 |
(PID.TID 0000.0001) ; |
1131 |
(PID.TID 0000.0001) |
1132 |
(PID.TID 0000.0001) Seaice dynamics configuration > START < |
1133 |
(PID.TID 0000.0001) ------------------------------------------ |
1134 |
(PID.TID 0000.0001) SEAICEuseDYNAMICS = /* use dynamics */ |
1135 |
(PID.TID 0000.0001) T |
1136 |
(PID.TID 0000.0001) ; |
1137 |
(PID.TID 0000.0001) model grid type = /* type of sea ice model grid */ |
1138 |
(PID.TID 0000.0001) 'C-GRID' |
1139 |
(PID.TID 0000.0001) ; |
1140 |
(PID.TID 0000.0001) SEAICEuseStrImpCpl = /* use strongly implicit coupling */ |
1141 |
(PID.TID 0000.0001) F |
1142 |
(PID.TID 0000.0001) ; |
1143 |
(PID.TID 0000.0001) SEAICEuseEVP = /* use EVP solver rather than LSR */ |
1144 |
(PID.TID 0000.0001) F |
1145 |
(PID.TID 0000.0001) ; |
1146 |
(PID.TID 0000.0001) SEAICEuseFREEDRIFT = /* use free drift solution */ |
1147 |
(PID.TID 0000.0001) F |
1148 |
(PID.TID 0000.0001) ; |
1149 |
(PID.TID 0000.0001) OCEAN_drag = /* air-ocean drag coefficient */ |
1150 |
(PID.TID 0000.0001) 8.154100000000000E-04 |
1151 |
(PID.TID 0000.0001) ; |
1152 |
(PID.TID 0000.0001) SEAICE_drag = /* air-ice drag coefficient */ |
1153 |
(PID.TID 0000.0001) 2.000000000000000E-03 |
1154 |
(PID.TID 0000.0001) ; |
1155 |
(PID.TID 0000.0001) SEAICE_drag_south = /* Southern Ocean SEAICE_drag */ |
1156 |
(PID.TID 0000.0001) 2.000000000000000E-03 |
1157 |
(PID.TID 0000.0001) ; |
1158 |
(PID.TID 0000.0001) SEAICE_waterDrag = /* water-ice drag * density */ |
1159 |
(PID.TID 0000.0001) 5.350800000000000E+00 |
1160 |
(PID.TID 0000.0001) ; |
1161 |
(PID.TID 0000.0001) SEAICE_waterDrag_south = /* Southern Ocean waterDrag */ |
1162 |
(PID.TID 0000.0001) 5.350800000000000E+00 |
1163 |
(PID.TID 0000.0001) ; |
1164 |
(PID.TID 0000.0001) SEAICEuseTilt = /* include surface tilt in dyna. */ |
1165 |
(PID.TID 0000.0001) T |
1166 |
(PID.TID 0000.0001) ; |
1167 |
(PID.TID 0000.0001) SEAICEuseTEM = /* use truncated ellipse rheology */ |
1168 |
(PID.TID 0000.0001) F |
1169 |
(PID.TID 0000.0001) ; |
1170 |
(PID.TID 0000.0001) SEAICE_strength = /* sea-ice strength Pstar */ |
1171 |
(PID.TID 0000.0001) 2.678000000000000E+04 |
1172 |
(PID.TID 0000.0001) ; |
1173 |
(PID.TID 0000.0001) SEAICE_cStar = /* sea-ice strength parameter cStar */ |
1174 |
(PID.TID 0000.0001) 2.000000000000000E+01 |
1175 |
(PID.TID 0000.0001) ; |
1176 |
(PID.TID 0000.0001) SEAICE_tensilFac = /* sea-ice tensile strength factor */ |
1177 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1178 |
(PID.TID 0000.0001) ; |
1179 |
(PID.TID 0000.0001) SEAICE_tensilDepth= /* crit. depth for tensile strength */ |
1180 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1181 |
(PID.TID 0000.0001) ; |
1182 |
(PID.TID 0000.0001) SEAICEpresH0 = /* sea-ice strength Heff threshold */ |
1183 |
(PID.TID 0000.0001) 1.000000000000000E+00 |
1184 |
(PID.TID 0000.0001) ; |
1185 |
(PID.TID 0000.0001) SEAICEpresPow0 = /* exponent for Heff<SEAICEpresH0 */ |
1186 |
(PID.TID 0000.0001) 1 |
1187 |
(PID.TID 0000.0001) ; |
1188 |
(PID.TID 0000.0001) SEAICEpresPow1 = /* exponent for Heff>SEAICEpresH0 */ |
1189 |
(PID.TID 0000.0001) 1 |
1190 |
(PID.TID 0000.0001) ; |
1191 |
(PID.TID 0000.0001) SEAICEetaZmethod = /* method computing eta at Z-point */ |
1192 |
(PID.TID 0000.0001) 3 |
1193 |
(PID.TID 0000.0001) ; |
1194 |
(PID.TID 0000.0001) SEAICE_zetaMin = /* lower bound for viscosity */ |
1195 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1196 |
(PID.TID 0000.0001) ; |
1197 |
(PID.TID 0000.0001) SEAICE_eccen = /* elliptical yield curve eccent */ |
1198 |
(PID.TID 0000.0001) 2.000000000000000E+00 |
1199 |
(PID.TID 0000.0001) ; |
1200 |
(PID.TID 0000.0001) SEAICEstressFactor = /* wind stress scaling factor */ |
1201 |
(PID.TID 0000.0001) 1.000000000000000E+00 |
1202 |
(PID.TID 0000.0001) ; |
1203 |
(PID.TID 0000.0001) SEAICE_airTurnAngle = /* air-ice turning angle */ |
1204 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1205 |
(PID.TID 0000.0001) ; |
1206 |
(PID.TID 0000.0001) SEAICE_waterTurnAngle = /* ice-water turning angle */ |
1207 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1208 |
(PID.TID 0000.0001) ; |
1209 |
(PID.TID 0000.0001) SEAICEuseMetricTerms = /* use metric terms */ |
1210 |
(PID.TID 0000.0001) T |
1211 |
(PID.TID 0000.0001) ; |
1212 |
(PID.TID 0000.0001) SEAICE_no_slip = /* no slip boundary conditions */ |
1213 |
(PID.TID 0000.0001) F |
1214 |
(PID.TID 0000.0001) ; |
1215 |
(PID.TID 0000.0001) SEAICE_clipVeloctities = /* impose max. vels. */ |
1216 |
(PID.TID 0000.0001) F |
1217 |
(PID.TID 0000.0001) ; |
1218 |
(PID.TID 0000.0001) useHB87stressCoupling = /* altern. ice-ocean stress */ |
1219 |
(PID.TID 0000.0001) F |
1220 |
(PID.TID 0000.0001) ; |
1221 |
(PID.TID 0000.0001) SEAICEscaleSurfStress = /* scale atm. and ocean-surface stress with AREA */ |
1222 |
(PID.TID 0000.0001) F |
1223 |
(PID.TID 0000.0001) ; |
1224 |
(PID.TID 0000.0001) SEAICE_maskRHS = /* mask RHS of solver */ |
1225 |
(PID.TID 0000.0001) F |
1226 |
(PID.TID 0000.0001) ; |
1227 |
(PID.TID 0000.0001) LSR_mixIniGuess = /* mix free-drift sol. into LSR initial Guess */ |
1228 |
(PID.TID 0000.0001) 0 |
1229 |
(PID.TID 0000.0001) ; |
1230 |
(PID.TID 0000.0001) SOLV_MAX_ITERS = /* max. number of LSR solver steps */ |
1231 |
(PID.TID 0000.0001) 10 |
1232 |
(PID.TID 0000.0001) ; |
1233 |
(PID.TID 0000.0001) SEAICE_LSRrelaxU = /* LSR solver: relaxation parameter */ |
1234 |
(PID.TID 0000.0001) 9.500000000000000E-01 |
1235 |
(PID.TID 0000.0001) ; |
1236 |
(PID.TID 0000.0001) SEAICE_LSRrelaxV = /* LSR solver: relaxation parameter */ |
1237 |
(PID.TID 0000.0001) 9.500000000000000E-01 |
1238 |
(PID.TID 0000.0001) ; |
1239 |
(PID.TID 0000.0001) LSR_ERROR = /* sets accuracy of LSR solver */ |
1240 |
(PID.TID 0000.0001) 1.000000000000000E-04 |
1241 |
(PID.TID 0000.0001) ; |
1242 |
(PID.TID 0000.0001) SOLV_NCHECK = /* test interval for LSR solver */ |
1243 |
(PID.TID 0000.0001) 2 |
1244 |
(PID.TID 0000.0001) ; |
1245 |
(PID.TID 0000.0001) NPSEUDOTIMESTEPS = /* num. of extra pseudo time steps */ |
1246 |
(PID.TID 0000.0001) 2 |
1247 |
(PID.TID 0000.0001) ; |
1248 |
(PID.TID 0000.0001) SEAICEuseMultiTileSolver = /* use full domain tri-diag solver */ |
1249 |
(PID.TID 0000.0001) F |
1250 |
(PID.TID 0000.0001) ; |
1251 |
(PID.TID 0000.0001) SEAICE_OLx = /* overlap for LSR/preconditioner */ |
1252 |
(PID.TID 0000.0001) 1 |
1253 |
(PID.TID 0000.0001) ; |
1254 |
(PID.TID 0000.0001) SEAICE_OLy = /* overlap for LSR/preconditioner */ |
1255 |
(PID.TID 0000.0001) 1 |
1256 |
(PID.TID 0000.0001) ; |
1257 |
(PID.TID 0000.0001) SEAICEuseIMEX = /* IMEX scheme with JFNK-solver */ |
1258 |
(PID.TID 0000.0001) F |
1259 |
(PID.TID 0000.0001) ; |
1260 |
(PID.TID 0000.0001) SEAICEnewtonIterMax = /* num. of JFNK Newton steps */ |
1261 |
(PID.TID 0000.0001) 200 |
1262 |
(PID.TID 0000.0001) ; |
1263 |
(PID.TID 0000.0001) SEAICEkrylovIterMax = /* num. of JFNK Krylov steps */ |
1264 |
(PID.TID 0000.0001) 50 |
1265 |
(PID.TID 0000.0001) ; |
1266 |
(PID.TID 0000.0001) SEAICE_JFNK_lsIter = /* start of line search */ |
1267 |
(PID.TID 0000.0001) 0 |
1268 |
(PID.TID 0000.0001) ; |
1269 |
(PID.TID 0000.0001) SEAICE_JFNK_tolIter = /* tol. is relaxed after this */ |
1270 |
(PID.TID 0000.0001) 100 |
1271 |
(PID.TID 0000.0001) ; |
1272 |
(PID.TID 0000.0001) JFNKgamma_nonlin= /* JFNK tolerance */ |
1273 |
(PID.TID 0000.0001) 1.000000000000000E-09 |
1274 |
(PID.TID 0000.0001) ; |
1275 |
(PID.TID 0000.0001) JFNKres_t= /* JFNK parameter */ |
1276 |
(PID.TID 0000.0001) 1.234567000000000E+05 |
1277 |
(PID.TID 0000.0001) ; |
1278 |
(PID.TID 0000.0001) JFNKres_tFac= /* JFNK parameter */ |
1279 |
(PID.TID 0000.0001) 5.000000000000000E-01 |
1280 |
(PID.TID 0000.0001) ; |
1281 |
(PID.TID 0000.0001) SEAICE_JFNKepsilon= /* JFNK: FD-gradient step size */ |
1282 |
(PID.TID 0000.0001) 1.000000000000000E-06 |
1283 |
(PID.TID 0000.0001) ; |
1284 |
(PID.TID 0000.0001) SEAICE_JFNKphi = /* JFNK: inexact Newtow parameter */ |
1285 |
(PID.TID 0000.0001) 1.000000000000000E+00 |
1286 |
(PID.TID 0000.0001) ; |
1287 |
(PID.TID 0000.0001) SEAICE_JFNKalpha = /* JFNK: inexact Newtow parameter */ |
1288 |
(PID.TID 0000.0001) 1.500000000000000E+00 |
1289 |
(PID.TID 0000.0001) ; |
1290 |
(PID.TID 0000.0001) |
1291 |
(PID.TID 0000.0001) Seaice advection diffusion config, > START < |
1292 |
(PID.TID 0000.0001) ----------------------------------------------- |
1293 |
(PID.TID 0000.0001) ==> advection diffusion done in pkg ThSIce |
1294 |
(PID.TID 0000.0001) |
1295 |
(PID.TID 0000.0001) Seaice thermodynamics configuration > START < |
1296 |
(PID.TID 0000.0001) ----------------------------------------------- |
1297 |
(PID.TID 0000.0001) SEAICE_rhoIce = /* density of sea ice (kg/m3) */ |
1298 |
(PID.TID 0000.0001) 9.100000000000000E+02 |
1299 |
(PID.TID 0000.0001) ; |
1300 |
(PID.TID 0000.0001) SEAICE_rhoSnow = /* density of snow (kg/m3) */ |
1301 |
(PID.TID 0000.0001) 3.300000000000000E+02 |
1302 |
(PID.TID 0000.0001) ; |
1303 |
(PID.TID 0000.0001) SEAICE_rhoAir = /* density of air (kg/m3) */ |
1304 |
(PID.TID 0000.0001) 1.200000000000000E+00 |
1305 |
(PID.TID 0000.0001) ; |
1306 |
(PID.TID 0000.0001) usePW79thermodynamics = /* default 0-layer TD */ |
1307 |
(PID.TID 0000.0001) F |
1308 |
(PID.TID 0000.0001) ; |
1309 |
(PID.TID 0000.0001) pkg/seaice thermodynamics is OFF |
1310 |
(PID.TID 0000.0001) |
1311 |
(PID.TID 0000.0001) Seaice initialization and IO config., > START < |
1312 |
(PID.TID 0000.0001) ------------------------------------------------- |
1313 |
(PID.TID 0000.0001) SEAICE_initialHEFF= /* initial sea-ice thickness */ |
1314 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1315 |
(PID.TID 0000.0001) ; |
1316 |
(PID.TID 0000.0001) AreaFile = /* Initial ice concentration File */ |
1317 |
(PID.TID 0000.0001) '' |
1318 |
(PID.TID 0000.0001) ; |
1319 |
(PID.TID 0000.0001) HeffFile = /* Initial effective ice thickness File */ |
1320 |
(PID.TID 0000.0001) '' |
1321 |
(PID.TID 0000.0001) ; |
1322 |
(PID.TID 0000.0001) HsnowFile = /* Initial snow thickness File */ |
1323 |
(PID.TID 0000.0001) '' |
1324 |
(PID.TID 0000.0001) ; |
1325 |
(PID.TID 0000.0001) uIceFile = /* Initial U-ice velocity File */ |
1326 |
(PID.TID 0000.0001) '' |
1327 |
(PID.TID 0000.0001) ; |
1328 |
(PID.TID 0000.0001) vIceFile = /* Initial V-ice velocity File */ |
1329 |
(PID.TID 0000.0001) '' |
1330 |
(PID.TID 0000.0001) ; |
1331 |
(PID.TID 0000.0001) SEAICEwriteState = /* write sea ice state to file */ |
1332 |
(PID.TID 0000.0001) T |
1333 |
(PID.TID 0000.0001) ; |
1334 |
(PID.TID 0000.0001) SEAICE_monFreq = /* monitor frequency */ |
1335 |
(PID.TID 0000.0001) 1.800000000000000E+03 |
1336 |
(PID.TID 0000.0001) ; |
1337 |
(PID.TID 0000.0001) SEAICE_dumpFreq = /* dump frequency */ |
1338 |
(PID.TID 0000.0001) 4.320000000000000E+05 |
1339 |
(PID.TID 0000.0001) ; |
1340 |
(PID.TID 0000.0001) SEAICE_taveFreq = /* time-averaging frequency */ |
1341 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1342 |
(PID.TID 0000.0001) ; |
1343 |
(PID.TID 0000.0001) SEAICE_mon_stdio = /* write monitor to std-outp */ |
1344 |
(PID.TID 0000.0001) T |
1345 |
(PID.TID 0000.0001) ; |
1346 |
(PID.TID 0000.0001) SEAICE_dump_mdsio = /* write snap-shot using MDSIO */ |
1347 |
(PID.TID 0000.0001) T |
1348 |
(PID.TID 0000.0001) ; |
1349 |
(PID.TID 0000.0001) SEAICE_tave_mdsio = /* write TimeAverage using MDSIO */ |
1350 |
(PID.TID 0000.0001) T |
1351 |
(PID.TID 0000.0001) ; |
1352 |
(PID.TID 0000.0001) |
1353 |
(PID.TID 0000.0001) Seaice regularization numbers, > START < |
1354 |
(PID.TID 0000.0001) ----------------------------------------------- |
1355 |
(PID.TID 0000.0001) SEAICE_deltaMin = /* reduce singularities in Delta */ |
1356 |
(PID.TID 0000.0001) 1.000000000000000E-10 |
1357 |
(PID.TID 0000.0001) ; |
1358 |
(PID.TID 0000.0001) SEAICE_EPS = /* small number */ |
1359 |
(PID.TID 0000.0001) 1.000000000000000E-10 |
1360 |
(PID.TID 0000.0001) ; |
1361 |
(PID.TID 0000.0001) SEAICE_EPS_SQ = /* small number squared */ |
1362 |
(PID.TID 0000.0001) 1.000000000000000E-20 |
1363 |
(PID.TID 0000.0001) ; |
1364 |
(PID.TID 0000.0001) SEAICE_area_reg = /* reduce derivative singularities */ |
1365 |
(PID.TID 0000.0001) 1.000000000000000E-05 |
1366 |
(PID.TID 0000.0001) ; |
1367 |
(PID.TID 0000.0001) SEAICE_hice_reg = /* reduce derivative singularities */ |
1368 |
(PID.TID 0000.0001) 5.000000000000000E-02 |
1369 |
(PID.TID 0000.0001) ; |
1370 |
(PID.TID 0000.0001) SEAICE_area_floor = /* reduce derivative singularities */ |
1371 |
(PID.TID 0000.0001) 1.000000000000000E-05 |
1372 |
(PID.TID 0000.0001) ; |
1373 |
(PID.TID 0000.0001) |
1374 |
(PID.TID 0000.0001) // ======================================================= |
1375 |
(PID.TID 0000.0001) // Seaice configuration (SEAICE_PARM01) >>> END <<< |
1376 |
(PID.TID 0000.0001) // ======================================================= |
1377 |
(PID.TID 0000.0001) |
1378 |
(PID.TID 0000.0001) ------------------------------------------------------------ |
1379 |
(PID.TID 0000.0001) DIAGNOSTICS_SET_LEVELS: done |
1380 |
(PID.TID 0000.0001) Total Nb of available Diagnostics: ndiagt= 246 |
1381 |
(PID.TID 0000.0001) write list of available Diagnostics to file: available_diagnostics.log |
1382 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 153 SIuice |
1383 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 154 SIvice |
1384 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 147 SIheff |
1385 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 214 SI_Fract |
1386 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 215 SI_Thick |
1387 |
(PID.TID 0000.0001) - NOTE - SETDIAG: Counter-mate # 214 SI_Fract is already set |
1388 |
(PID.TID 0000.0001) space allocated for all diagnostics: 5 levels |
1389 |
(PID.TID 0000.0001) set mate pointer for diag # 153 SIuice , Parms: UU M1 , mate: 154 |
1390 |
(PID.TID 0000.0001) set mate pointer for diag # 154 SIvice , Parms: VV M1 , mate: 153 |
1391 |
(PID.TID 0000.0001) DIAGNOSTICS_SET_POINTERS: Set levels for Outp.Stream: snapshot |
1392 |
(PID.TID 0000.0001) Levels: 1. |
1393 |
(PID.TID 0000.0001) DIAGNOSTICS_SET_POINTERS: done |
1394 |
(PID.TID 0000.0001) ------------------------------------------------------------ |
1395 |
(PID.TID 0000.0001) DIAGSTATS_SET_REGIONS: define no region |
1396 |
(PID.TID 0000.0001) ------------------------------------------------------------ |
1397 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 214 SI_Fract |
1398 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 215 SI_Thick |
1399 |
(PID.TID 0000.0001) - NOTE - SETDIAG: Counter Diagnostic # 214 SI_Fract has already been set |
1400 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 144 SIarea |
1401 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 147 SIheff |
1402 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 153 SIuice |
1403 |
(PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 154 SIvice |
1404 |
(PID.TID 0000.0001) space allocated for all stats-diags: 6 levels |
1405 |
(PID.TID 0000.0001) DIAGSTATS_SET_POINTERS: done |
1406 |
(PID.TID 0000.0001) ------------------------------------------------------------ |
1407 |
(PID.TID 0000.0001) DIAGSTATS_INI_IO: open file: iceStDiag.0000000000.txt , unit= 9 |
1408 |
(PID.TID 0000.0001) %MON fCori_max = 0.0000000000000E+00 |
1409 |
(PID.TID 0000.0001) %MON fCori_min = 0.0000000000000E+00 |
1410 |
(PID.TID 0000.0001) %MON fCori_mean = 0.0000000000000E+00 |
1411 |
(PID.TID 0000.0001) %MON fCori_sd = 0.0000000000000E+00 |
1412 |
(PID.TID 0000.0001) %MON fCoriG_max = 0.0000000000000E+00 |
1413 |
(PID.TID 0000.0001) %MON fCoriG_min = 0.0000000000000E+00 |
1414 |
(PID.TID 0000.0001) %MON fCoriG_mean = 0.0000000000000E+00 |
1415 |
(PID.TID 0000.0001) %MON fCoriG_sd = 0.0000000000000E+00 |
1416 |
(PID.TID 0000.0001) %MON fCoriCos_max = 0.0000000000000E+00 |
1417 |
(PID.TID 0000.0001) %MON fCoriCos_min = 0.0000000000000E+00 |
1418 |
(PID.TID 0000.0001) %MON fCoriCos_mean = 0.0000000000000E+00 |
1419 |
(PID.TID 0000.0001) %MON fCoriCos_sd = 0.0000000000000E+00 |
1420 |
(PID.TID 0000.0001) INI_CG2D: CG2D normalisation factor = 1.0000000000000001E-01 |
1421 |
(PID.TID 0000.0001) |
1422 |
(PID.TID 0000.0001) // ======================================================= |
1423 |
(PID.TID 0000.0001) // Model configuration |
1424 |
(PID.TID 0000.0001) // ======================================================= |
1425 |
(PID.TID 0000.0001) // |
1426 |
(PID.TID 0000.0001) // "Physical" paramters ( PARM01 in namelist ) |
1427 |
(PID.TID 0000.0001) // |
1428 |
(PID.TID 0000.0001) buoyancyRelation = /* Type of relation to get Buoyancy */ |
1429 |
(PID.TID 0000.0001) 'OCEANIC' |
1430 |
(PID.TID 0000.0001) ; |
1431 |
(PID.TID 0000.0001) fluidIsAir = /* fluid major constituent is Air */ |
1432 |
(PID.TID 0000.0001) F |
1433 |
(PID.TID 0000.0001) ; |
1434 |
(PID.TID 0000.0001) fluidIsWater = /* fluid major constituent is Water */ |
1435 |
(PID.TID 0000.0001) T |
1436 |
(PID.TID 0000.0001) ; |
1437 |
(PID.TID 0000.0001) usingPCoords = /* use p (or p*) vertical coordinate */ |
1438 |
(PID.TID 0000.0001) F |
1439 |
(PID.TID 0000.0001) ; |
1440 |
(PID.TID 0000.0001) usingZCoords = /* use z (or z*) vertical coordinate */ |
1441 |
(PID.TID 0000.0001) T |
1442 |
(PID.TID 0000.0001) ; |
1443 |
(PID.TID 0000.0001) tRef = /* Reference temperature profile ( oC or K ) */ |
1444 |
(PID.TID 0000.0001) -1.620000000000000E+00 /* K = 1 */ |
1445 |
(PID.TID 0000.0001) ; |
1446 |
(PID.TID 0000.0001) sRef = /* Reference salinity profile ( psu ) */ |
1447 |
(PID.TID 0000.0001) 3.000000000000000E+01 /* K = 1 */ |
1448 |
(PID.TID 0000.0001) ; |
1449 |
(PID.TID 0000.0001) useStrainTensionVisc= /* Use StrainTension Form of Viscous Operator */ |
1450 |
(PID.TID 0000.0001) F |
1451 |
(PID.TID 0000.0001) ; |
1452 |
(PID.TID 0000.0001) useVariableVisc = /* Use variable horizontal viscosity */ |
1453 |
(PID.TID 0000.0001) F |
1454 |
(PID.TID 0000.0001) ; |
1455 |
(PID.TID 0000.0001) useHarmonicVisc = /* Use harmonic horizontal viscosity */ |
1456 |
(PID.TID 0000.0001) F |
1457 |
(PID.TID 0000.0001) ; |
1458 |
(PID.TID 0000.0001) useBiharmonicVisc= /* Use biharmonic horiz. viscosity */ |
1459 |
(PID.TID 0000.0001) F |
1460 |
(PID.TID 0000.0001) ; |
1461 |
(PID.TID 0000.0001) useSmag3D = /* Use isotropic 3-D Smagorinsky viscosity */ |
1462 |
(PID.TID 0000.0001) F |
1463 |
(PID.TID 0000.0001) ; |
1464 |
(PID.TID 0000.0001) viscAh = /* Lateral harmonic viscosity ( m^2/s ) */ |
1465 |
(PID.TID 0000.0001) 3.000000000000000E+02 |
1466 |
(PID.TID 0000.0001) ; |
1467 |
(PID.TID 0000.0001) viscA4 = /* Lateral biharmonic viscosity ( m^4/s ) */ |
1468 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1469 |
(PID.TID 0000.0001) ; |
1470 |
(PID.TID 0000.0001) no_slip_sides = /* Viscous BCs: No-slip sides */ |
1471 |
(PID.TID 0000.0001) F |
1472 |
(PID.TID 0000.0001) ; |
1473 |
(PID.TID 0000.0001) sideDragFactor = /* side-drag scaling factor (non-dim) */ |
1474 |
(PID.TID 0000.0001) 2.000000000000000E+00 |
1475 |
(PID.TID 0000.0001) ; |
1476 |
(PID.TID 0000.0001) viscArNr = /* vertical profile of vertical viscosity ( m^2/s )*/ |
1477 |
(PID.TID 0000.0001) 3.000000000000000E-02 /* K = 1 */ |
1478 |
(PID.TID 0000.0001) ; |
1479 |
(PID.TID 0000.0001) no_slip_bottom = /* Viscous BCs: No-slip bottom */ |
1480 |
(PID.TID 0000.0001) T |
1481 |
(PID.TID 0000.0001) ; |
1482 |
(PID.TID 0000.0001) bottomVisc_pCell = /* Partial-cell in bottom Visc. BC */ |
1483 |
(PID.TID 0000.0001) F |
1484 |
(PID.TID 0000.0001) ; |
1485 |
(PID.TID 0000.0001) bottomDragLinear = /* linear bottom-drag coefficient ( m/s ) */ |
1486 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1487 |
(PID.TID 0000.0001) ; |
1488 |
(PID.TID 0000.0001) bottomDragQuadratic = /* quadratic bottom-drag coefficient (-) */ |
1489 |
(PID.TID 0000.0001) 5.000000000000000E-03 |
1490 |
(PID.TID 0000.0001) ; |
1491 |
(PID.TID 0000.0001) selectBotDragQuadr = /* select quadratic bottom drag options */ |
1492 |
(PID.TID 0000.0001) -1 |
1493 |
(PID.TID 0000.0001) ; |
1494 |
(PID.TID 0000.0001) diffKhT = /* Laplacian diffusion of heat laterally ( m^2/s ) */ |
1495 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1496 |
(PID.TID 0000.0001) ; |
1497 |
(PID.TID 0000.0001) diffK4T = /* Biharmonic diffusion of heat laterally ( m^4/s ) */ |
1498 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1499 |
(PID.TID 0000.0001) ; |
1500 |
(PID.TID 0000.0001) diffKhS = /* Laplacian diffusion of salt laterally ( m^2/s ) */ |
1501 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1502 |
(PID.TID 0000.0001) ; |
1503 |
(PID.TID 0000.0001) diffK4S = /* Biharmonic diffusion of salt laterally ( m^4/s ) */ |
1504 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1505 |
(PID.TID 0000.0001) ; |
1506 |
(PID.TID 0000.0001) diffKrNrT = /* vertical profile of vertical diffusion of Temp ( m^2/s )*/ |
1507 |
(PID.TID 0000.0001) 0.000000000000000E+00 /* K = 1 */ |
1508 |
(PID.TID 0000.0001) ; |
1509 |
(PID.TID 0000.0001) diffKrNrS = /* vertical profile of vertical diffusion of Salt ( m^2/s )*/ |
1510 |
(PID.TID 0000.0001) 0.000000000000000E+00 /* K = 1 */ |
1511 |
(PID.TID 0000.0001) ; |
1512 |
(PID.TID 0000.0001) diffKrBL79surf = /* Surface diffusion for Bryan and Lewis 79 ( m^2/s ) */ |
1513 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1514 |
(PID.TID 0000.0001) ; |
1515 |
(PID.TID 0000.0001) diffKrBL79deep = /* Deep diffusion for Bryan and Lewis 1979 ( m^2/s ) */ |
1516 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1517 |
(PID.TID 0000.0001) ; |
1518 |
(PID.TID 0000.0001) diffKrBL79scl = /* Depth scale for Bryan and Lewis 1979 ( m ) */ |
1519 |
(PID.TID 0000.0001) 2.000000000000000E+02 |
1520 |
(PID.TID 0000.0001) ; |
1521 |
(PID.TID 0000.0001) diffKrBL79Ho = /* Turning depth for Bryan and Lewis 1979 ( m ) */ |
1522 |
(PID.TID 0000.0001) -2.000000000000000E+03 |
1523 |
(PID.TID 0000.0001) ; |
1524 |
(PID.TID 0000.0001) ivdc_kappa = /* Implicit Vertical Diffusivity for Convection ( m^2/s) */ |
1525 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1526 |
(PID.TID 0000.0001) ; |
1527 |
(PID.TID 0000.0001) hMixCriteria= /* Criteria for mixed-layer diagnostic */ |
1528 |
(PID.TID 0000.0001) -8.000000000000000E-01 |
1529 |
(PID.TID 0000.0001) ; |
1530 |
(PID.TID 0000.0001) dRhoSmall = /* Parameter for mixed-layer diagnostic */ |
1531 |
(PID.TID 0000.0001) 1.000000000000000E-06 |
1532 |
(PID.TID 0000.0001) ; |
1533 |
(PID.TID 0000.0001) hMixSmooth= /* Smoothing parameter for mixed-layer diagnostic */ |
1534 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1535 |
(PID.TID 0000.0001) ; |
1536 |
(PID.TID 0000.0001) eosType = /* Type of Equation of State */ |
1537 |
(PID.TID 0000.0001) 'LINEAR' |
1538 |
(PID.TID 0000.0001) ; |
1539 |
(PID.TID 0000.0001) tAlpha = /* Linear EOS thermal expansion coefficient ( 1/oC ) */ |
1540 |
(PID.TID 0000.0001) 2.000000000000000E-04 |
1541 |
(PID.TID 0000.0001) ; |
1542 |
(PID.TID 0000.0001) sBeta = /* Linear EOS haline contraction coefficient ( 1/psu ) */ |
1543 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1544 |
(PID.TID 0000.0001) ; |
1545 |
(PID.TID 0000.0001) rhoNil = /* Reference density for Linear EOS ( kg/m^3 ) */ |
1546 |
(PID.TID 0000.0001) 1.030000000000000E+03 |
1547 |
(PID.TID 0000.0001) ; |
1548 |
(PID.TID 0000.0001) HeatCapacity_Cp = /* Specific heat capacity ( J/kg/K ) */ |
1549 |
(PID.TID 0000.0001) 3.986000000000000E+03 |
1550 |
(PID.TID 0000.0001) ; |
1551 |
(PID.TID 0000.0001) celsius2K = /* 0 degree Celsius converted to Kelvin ( K ) */ |
1552 |
(PID.TID 0000.0001) 2.731500000000000E+02 |
1553 |
(PID.TID 0000.0001) ; |
1554 |
(PID.TID 0000.0001) rhoConst = /* Reference density (Boussinesq) ( kg/m^3 ) */ |
1555 |
(PID.TID 0000.0001) 1.030000000000000E+03 |
1556 |
(PID.TID 0000.0001) ; |
1557 |
(PID.TID 0000.0001) rhoFacC = /* normalized Reference density @ cell-Center (-) */ |
1558 |
(PID.TID 0000.0001) 1.000000000000000E+00 /* K = 1 */ |
1559 |
(PID.TID 0000.0001) ; |
1560 |
(PID.TID 0000.0001) rhoFacF = /* normalized Reference density @ W-Interface (-) */ |
1561 |
(PID.TID 0000.0001) 2 @ 1.000000000000000E+00 /* K = 1: 2 */ |
1562 |
(PID.TID 0000.0001) ; |
1563 |
(PID.TID 0000.0001) rhoConstFresh = /* Fresh-water reference density ( kg/m^3 ) */ |
1564 |
(PID.TID 0000.0001) 1.000000000000000E+03 |
1565 |
(PID.TID 0000.0001) ; |
1566 |
(PID.TID 0000.0001) gravity = /* Gravitational acceleration ( m/s^2 ) */ |
1567 |
(PID.TID 0000.0001) 9.810000000000000E+00 |
1568 |
(PID.TID 0000.0001) ; |
1569 |
(PID.TID 0000.0001) gBaro = /* Barotropic gravity ( m/s^2 ) */ |
1570 |
(PID.TID 0000.0001) 9.810000000000000E+00 |
1571 |
(PID.TID 0000.0001) ; |
1572 |
(PID.TID 0000.0001) rotationPeriod = /* Rotation Period ( s ) */ |
1573 |
(PID.TID 0000.0001) 8.616400000000000E+04 |
1574 |
(PID.TID 0000.0001) ; |
1575 |
(PID.TID 0000.0001) omega = /* Angular velocity ( rad/s ) */ |
1576 |
(PID.TID 0000.0001) 7.292123516990375E-05 |
1577 |
(PID.TID 0000.0001) ; |
1578 |
(PID.TID 0000.0001) f0 = /* Reference coriolis parameter ( 1/s ) */ |
1579 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1580 |
(PID.TID 0000.0001) ; |
1581 |
(PID.TID 0000.0001) beta = /* Beta ( 1/(m.s) ) */ |
1582 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1583 |
(PID.TID 0000.0001) ; |
1584 |
(PID.TID 0000.0001) fPrime = /* Second coriolis parameter ( 1/s ) */ |
1585 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1586 |
(PID.TID 0000.0001) ; |
1587 |
(PID.TID 0000.0001) rigidLid = /* Rigid lid on/off flag */ |
1588 |
(PID.TID 0000.0001) F |
1589 |
(PID.TID 0000.0001) ; |
1590 |
(PID.TID 0000.0001) implicitFreeSurface = /* Implicit free surface on/off flag */ |
1591 |
(PID.TID 0000.0001) T |
1592 |
(PID.TID 0000.0001) ; |
1593 |
(PID.TID 0000.0001) freeSurfFac = /* Implicit free surface factor */ |
1594 |
(PID.TID 0000.0001) 1.000000000000000E+00 |
1595 |
(PID.TID 0000.0001) ; |
1596 |
(PID.TID 0000.0001) implicSurfPress = /* Surface Pressure implicit factor (0-1)*/ |
1597 |
(PID.TID 0000.0001) 1.000000000000000E+00 |
1598 |
(PID.TID 0000.0001) ; |
1599 |
(PID.TID 0000.0001) implicDiv2Dflow = /* Barot. Flow Div. implicit factor (0-1)*/ |
1600 |
(PID.TID 0000.0001) 1.000000000000000E+00 |
1601 |
(PID.TID 0000.0001) ; |
1602 |
(PID.TID 0000.0001) uniformLin_PhiSurf = /* use uniform Bo_surf on/off flag*/ |
1603 |
(PID.TID 0000.0001) T |
1604 |
(PID.TID 0000.0001) ; |
1605 |
(PID.TID 0000.0001) uniformFreeSurfLev = /* free-surface level-index is uniform */ |
1606 |
(PID.TID 0000.0001) T |
1607 |
(PID.TID 0000.0001) ; |
1608 |
(PID.TID 0000.0001) hFacMin = /* minimum partial cell factor (hFac) */ |
1609 |
(PID.TID 0000.0001) 1.000000000000000E+00 |
1610 |
(PID.TID 0000.0001) ; |
1611 |
(PID.TID 0000.0001) hFacMinDr = /* minimum partial cell thickness ( m) */ |
1612 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1613 |
(PID.TID 0000.0001) ; |
1614 |
(PID.TID 0000.0001) exactConserv = /* Exact Volume Conservation on/off flag*/ |
1615 |
(PID.TID 0000.0001) F |
1616 |
(PID.TID 0000.0001) ; |
1617 |
(PID.TID 0000.0001) linFSConserveTr = /* Tracer correction for Lin Free Surface on/off flag*/ |
1618 |
(PID.TID 0000.0001) F |
1619 |
(PID.TID 0000.0001) ; |
1620 |
(PID.TID 0000.0001) nonlinFreeSurf = /* Non-linear Free Surf. options (-1,0,1,2,3)*/ |
1621 |
(PID.TID 0000.0001) 0 |
1622 |
(PID.TID 0000.0001) -1,0= Off ; 1,2,3= On, 2=+rescale gU,gV, 3=+update cg2d solv. |
1623 |
(PID.TID 0000.0001) ; |
1624 |
(PID.TID 0000.0001) hFacInf = /* lower threshold for hFac (nonlinFreeSurf only)*/ |
1625 |
(PID.TID 0000.0001) 2.000000000000000E-01 |
1626 |
(PID.TID 0000.0001) ; |
1627 |
(PID.TID 0000.0001) hFacSup = /* upper threshold for hFac (nonlinFreeSurf only)*/ |
1628 |
(PID.TID 0000.0001) 2.000000000000000E+00 |
1629 |
(PID.TID 0000.0001) ; |
1630 |
(PID.TID 0000.0001) select_rStar = /* r* Vertical coord. options (=0 r coord.; >0 uses r*)*/ |
1631 |
(PID.TID 0000.0001) 0 |
1632 |
(PID.TID 0000.0001) ; |
1633 |
(PID.TID 0000.0001) useRealFreshWaterFlux = /* Real Fresh Water Flux on/off flag*/ |
1634 |
(PID.TID 0000.0001) F |
1635 |
(PID.TID 0000.0001) ; |
1636 |
(PID.TID 0000.0001) temp_EvPrRn = /* Temp. of Evap/Prec/R (UNSET=use local T)(oC)*/ |
1637 |
(PID.TID 0000.0001) 1.234567000000000E+05 |
1638 |
(PID.TID 0000.0001) ; |
1639 |
(PID.TID 0000.0001) salt_EvPrRn = /* Salin. of Evap/Prec/R (UNSET=use local S)(psu)*/ |
1640 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1641 |
(PID.TID 0000.0001) ; |
1642 |
(PID.TID 0000.0001) selectAddFluid = /* option for mass source/sink of fluid (=0: off) */ |
1643 |
(PID.TID 0000.0001) 0 |
1644 |
(PID.TID 0000.0001) ; |
1645 |
(PID.TID 0000.0001) temp_addMass = /* Temp. of addMass array (UNSET=use local T)(oC)*/ |
1646 |
(PID.TID 0000.0001) 1.234567000000000E+05 |
1647 |
(PID.TID 0000.0001) ; |
1648 |
(PID.TID 0000.0001) salt_addMass = /* Salin. of addMass array (UNSET=use local S)(psu)*/ |
1649 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1650 |
(PID.TID 0000.0001) ; |
1651 |
(PID.TID 0000.0001) convertFW2Salt = /* convert F.W. Flux to Salt Flux (-1=use local S)(psu)*/ |
1652 |
(PID.TID 0000.0001) -1.000000000000000E+00 |
1653 |
(PID.TID 0000.0001) ; |
1654 |
(PID.TID 0000.0001) use3Dsolver = /* use 3-D pressure solver on/off flag */ |
1655 |
(PID.TID 0000.0001) F |
1656 |
(PID.TID 0000.0001) ; |
1657 |
(PID.TID 0000.0001) nonHydrostatic = /* Non-Hydrostatic on/off flag */ |
1658 |
(PID.TID 0000.0001) F |
1659 |
(PID.TID 0000.0001) ; |
1660 |
(PID.TID 0000.0001) nh_Am2 = /* Non-Hydrostatic terms scaling factor */ |
1661 |
(PID.TID 0000.0001) 1.000000000000000E+00 |
1662 |
(PID.TID 0000.0001) ; |
1663 |
(PID.TID 0000.0001) implicitNHPress = /* Non-Hyd Pressure implicit factor (0-1)*/ |
1664 |
(PID.TID 0000.0001) 1.000000000000000E+00 |
1665 |
(PID.TID 0000.0001) ; |
1666 |
(PID.TID 0000.0001) selectNHfreeSurf = /* Non-Hyd (free-)Surface option */ |
1667 |
(PID.TID 0000.0001) 0 |
1668 |
(PID.TID 0000.0001) ; |
1669 |
(PID.TID 0000.0001) quasiHydrostatic = /* Quasi-Hydrostatic on/off flag */ |
1670 |
(PID.TID 0000.0001) F |
1671 |
(PID.TID 0000.0001) ; |
1672 |
(PID.TID 0000.0001) calc_wVelocity = /* vertical velocity calculation on/off flag */ |
1673 |
(PID.TID 0000.0001) F |
1674 |
(PID.TID 0000.0001) ; |
1675 |
(PID.TID 0000.0001) momStepping = /* Momentum equation on/off flag */ |
1676 |
(PID.TID 0000.0001) F |
1677 |
(PID.TID 0000.0001) ; |
1678 |
(PID.TID 0000.0001) vectorInvariantMomentum= /* Vector-Invariant Momentum on/off */ |
1679 |
(PID.TID 0000.0001) F |
1680 |
(PID.TID 0000.0001) ; |
1681 |
(PID.TID 0000.0001) momAdvection = /* Momentum advection on/off flag */ |
1682 |
(PID.TID 0000.0001) F |
1683 |
(PID.TID 0000.0001) ; |
1684 |
(PID.TID 0000.0001) momViscosity = /* Momentum viscosity on/off flag */ |
1685 |
(PID.TID 0000.0001) F |
1686 |
(PID.TID 0000.0001) ; |
1687 |
(PID.TID 0000.0001) momImplVertAdv= /* Momentum implicit vert. advection on/off*/ |
1688 |
(PID.TID 0000.0001) F |
1689 |
(PID.TID 0000.0001) ; |
1690 |
(PID.TID 0000.0001) implicitViscosity = /* Implicit viscosity on/off flag */ |
1691 |
(PID.TID 0000.0001) F |
1692 |
(PID.TID 0000.0001) ; |
1693 |
(PID.TID 0000.0001) implBottomFriction= /* Implicit bottom friction on/off flag */ |
1694 |
(PID.TID 0000.0001) F |
1695 |
(PID.TID 0000.0001) ; |
1696 |
(PID.TID 0000.0001) metricTerms = /* metric-Terms on/off flag */ |
1697 |
(PID.TID 0000.0001) F |
1698 |
(PID.TID 0000.0001) ; |
1699 |
(PID.TID 0000.0001) useNHMTerms = /* Non-Hydrostatic Metric-Terms on/off */ |
1700 |
(PID.TID 0000.0001) F |
1701 |
(PID.TID 0000.0001) ; |
1702 |
(PID.TID 0000.0001) selectCoriMap = /* Coriolis Map options (0,1,2,3)*/ |
1703 |
(PID.TID 0000.0001) 1 |
1704 |
(PID.TID 0000.0001) 0= f-Plane ; 1= Beta-Plane ; 2= Spherical ; 3= read from file |
1705 |
(PID.TID 0000.0001) ; |
1706 |
(PID.TID 0000.0001) use3dCoriolis = /* 3-D Coriolis on/off flag */ |
1707 |
(PID.TID 0000.0001) F |
1708 |
(PID.TID 0000.0001) ; |
1709 |
(PID.TID 0000.0001) useCoriolis = /* Coriolis on/off flag */ |
1710 |
(PID.TID 0000.0001) F |
1711 |
(PID.TID 0000.0001) ; |
1712 |
(PID.TID 0000.0001) useCDscheme = /* CD scheme on/off flag */ |
1713 |
(PID.TID 0000.0001) F |
1714 |
(PID.TID 0000.0001) ; |
1715 |
(PID.TID 0000.0001) useEnergyConservingCoriolis= /* Flx-Form Coriolis scheme flag */ |
1716 |
(PID.TID 0000.0001) F |
1717 |
(PID.TID 0000.0001) ; |
1718 |
(PID.TID 0000.0001) useJamartWetPoints= /* Coriolis WetPoints method flag */ |
1719 |
(PID.TID 0000.0001) T |
1720 |
(PID.TID 0000.0001) ; |
1721 |
(PID.TID 0000.0001) useJamartMomAdv= /* V.I Non-linear terms Jamart flag */ |
1722 |
(PID.TID 0000.0001) F |
1723 |
(PID.TID 0000.0001) ; |
1724 |
(PID.TID 0000.0001) useAbsVorticity= /* V.I Works with f+zeta in Coriolis */ |
1725 |
(PID.TID 0000.0001) F |
1726 |
(PID.TID 0000.0001) ; |
1727 |
(PID.TID 0000.0001) selectVortScheme= /* V.I Scheme selector for Vorticity-Term */ |
1728 |
(PID.TID 0000.0001) 123456789 |
1729 |
(PID.TID 0000.0001) = 0 : enstrophy (Shallow-Water Eq.) conserving scheme by Sadourny, JAS 75 |
1730 |
(PID.TID 0000.0001) = 1 : same as 0 with modified hFac |
1731 |
(PID.TID 0000.0001) = 2 : energy conserving scheme (used by Sadourny in JAS 75 paper) |
1732 |
(PID.TID 0000.0001) = 3 : energy (general) and enstrophy (2D, nonDiv.) conserving scheme |
1733 |
(PID.TID 0000.0001) from Sadourny (Burridge & Haseler, ECMWF Rep.4, 1977) |
1734 |
(PID.TID 0000.0001) ; |
1735 |
(PID.TID 0000.0001) upwindVorticity= /* V.I Upwind bias vorticity flag */ |
1736 |
(PID.TID 0000.0001) F |
1737 |
(PID.TID 0000.0001) ; |
1738 |
(PID.TID 0000.0001) highOrderVorticity= /* V.I High order vort. advect. flag */ |
1739 |
(PID.TID 0000.0001) F |
1740 |
(PID.TID 0000.0001) ; |
1741 |
(PID.TID 0000.0001) upwindShear= /* V.I Upwind vertical Shear advection flag */ |
1742 |
(PID.TID 0000.0001) F |
1743 |
(PID.TID 0000.0001) ; |
1744 |
(PID.TID 0000.0001) selectKEscheme= /* V.I Kinetic Energy scheme selector */ |
1745 |
(PID.TID 0000.0001) 0 |
1746 |
(PID.TID 0000.0001) ; |
1747 |
(PID.TID 0000.0001) momForcing = /* Momentum forcing on/off flag */ |
1748 |
(PID.TID 0000.0001) F |
1749 |
(PID.TID 0000.0001) ; |
1750 |
(PID.TID 0000.0001) momPressureForcing = /* Momentum pressure term on/off flag */ |
1751 |
(PID.TID 0000.0001) F |
1752 |
(PID.TID 0000.0001) ; |
1753 |
(PID.TID 0000.0001) implicitIntGravWave= /* Implicit Internal Gravity Wave flag */ |
1754 |
(PID.TID 0000.0001) F |
1755 |
(PID.TID 0000.0001) ; |
1756 |
(PID.TID 0000.0001) staggerTimeStep = /* Stagger time stepping on/off flag */ |
1757 |
(PID.TID 0000.0001) T |
1758 |
(PID.TID 0000.0001) ; |
1759 |
(PID.TID 0000.0001) doResetHFactors = /* reset thickness factors @ each time-step */ |
1760 |
(PID.TID 0000.0001) F |
1761 |
(PID.TID 0000.0001) ; |
1762 |
(PID.TID 0000.0001) multiDimAdvection = /* enable/disable Multi-Dim Advection */ |
1763 |
(PID.TID 0000.0001) T |
1764 |
(PID.TID 0000.0001) ; |
1765 |
(PID.TID 0000.0001) useMultiDimAdvec = /* Multi-Dim Advection is/is-not used */ |
1766 |
(PID.TID 0000.0001) F |
1767 |
(PID.TID 0000.0001) ; |
1768 |
(PID.TID 0000.0001) implicitDiffusion = /* Implicit Diffusion on/off flag */ |
1769 |
(PID.TID 0000.0001) F |
1770 |
(PID.TID 0000.0001) ; |
1771 |
(PID.TID 0000.0001) tempStepping = /* Temperature equation on/off flag */ |
1772 |
(PID.TID 0000.0001) F |
1773 |
(PID.TID 0000.0001) ; |
1774 |
(PID.TID 0000.0001) tempAdvection = /* Temperature advection on/off flag */ |
1775 |
(PID.TID 0000.0001) F |
1776 |
(PID.TID 0000.0001) ; |
1777 |
(PID.TID 0000.0001) tempImplVertAdv = /* Temp. implicit vert. advection on/off */ |
1778 |
(PID.TID 0000.0001) F |
1779 |
(PID.TID 0000.0001) ; |
1780 |
(PID.TID 0000.0001) tempForcing = /* Temperature forcing on/off flag */ |
1781 |
(PID.TID 0000.0001) F |
1782 |
(PID.TID 0000.0001) ; |
1783 |
(PID.TID 0000.0001) doThetaClimRelax = /* apply SST relaxation on/off flag */ |
1784 |
(PID.TID 0000.0001) F |
1785 |
(PID.TID 0000.0001) ; |
1786 |
(PID.TID 0000.0001) tempIsActiveTr = /* Temp. is a dynamically Active Tracer */ |
1787 |
(PID.TID 0000.0001) F |
1788 |
(PID.TID 0000.0001) ; |
1789 |
(PID.TID 0000.0001) saltStepping = /* Salinity equation on/off flag */ |
1790 |
(PID.TID 0000.0001) F |
1791 |
(PID.TID 0000.0001) ; |
1792 |
(PID.TID 0000.0001) saltAdvection = /* Salinity advection on/off flag */ |
1793 |
(PID.TID 0000.0001) F |
1794 |
(PID.TID 0000.0001) ; |
1795 |
(PID.TID 0000.0001) saltImplVertAdv = /* Sali. implicit vert. advection on/off */ |
1796 |
(PID.TID 0000.0001) F |
1797 |
(PID.TID 0000.0001) ; |
1798 |
(PID.TID 0000.0001) saltForcing = /* Salinity forcing on/off flag */ |
1799 |
(PID.TID 0000.0001) F |
1800 |
(PID.TID 0000.0001) ; |
1801 |
(PID.TID 0000.0001) doSaltClimRelax = /* apply SSS relaxation on/off flag */ |
1802 |
(PID.TID 0000.0001) F |
1803 |
(PID.TID 0000.0001) ; |
1804 |
(PID.TID 0000.0001) saltIsActiveTr = /* Salt is a dynamically Active Tracer */ |
1805 |
(PID.TID 0000.0001) F |
1806 |
(PID.TID 0000.0001) ; |
1807 |
(PID.TID 0000.0001) readBinaryPrec = /* Precision used for reading binary files */ |
1808 |
(PID.TID 0000.0001) 64 |
1809 |
(PID.TID 0000.0001) ; |
1810 |
(PID.TID 0000.0001) writeBinaryPrec = /* Precision used for writing binary files */ |
1811 |
(PID.TID 0000.0001) 64 |
1812 |
(PID.TID 0000.0001) ; |
1813 |
(PID.TID 0000.0001) globalFiles = /* write "global" (=not per tile) files */ |
1814 |
(PID.TID 0000.0001) F |
1815 |
(PID.TID 0000.0001) ; |
1816 |
(PID.TID 0000.0001) useSingleCpuIO = /* only master MPI process does I/O */ |
1817 |
(PID.TID 0000.0001) T |
1818 |
(PID.TID 0000.0001) ; |
1819 |
(PID.TID 0000.0001) useSingleCpuInput = /* only master process reads input */ |
1820 |
(PID.TID 0000.0001) T |
1821 |
(PID.TID 0000.0001) ; |
1822 |
(PID.TID 0000.0001) /* debLev[*] : level of debug & auxiliary message printing */ |
1823 |
(PID.TID 0000.0001) debLevZero = 0 ; /* level of disabled aux. msg printing */ |
1824 |
(PID.TID 0000.0001) debLevA = 1 ; /* level of minimum aux. msg printing */ |
1825 |
(PID.TID 0000.0001) debLevB = 2 ; /* level of low aux. print (report read-file opening)*/ |
1826 |
(PID.TID 0000.0001) debLevC = 3 ; /* level of moderate debug prt (most pkgs debug msg) */ |
1827 |
(PID.TID 0000.0001) debLevD = 4 ; /* level of enhanced debug prt (add DEBUG_STATS prt) */ |
1828 |
(PID.TID 0000.0001) debLevE = 5 ; /* level of extensive debug printing */ |
1829 |
(PID.TID 0000.0001) debugLevel = /* select debug printing level */ |
1830 |
(PID.TID 0000.0001) 2 |
1831 |
(PID.TID 0000.0001) ; |
1832 |
(PID.TID 0000.0001) // |
1833 |
(PID.TID 0000.0001) // Elliptic solver(s) paramters ( PARM02 in namelist ) |
1834 |
(PID.TID 0000.0001) // |
1835 |
(PID.TID 0000.0001) cg2dMaxIters = /* Upper limit on 2d con. grad iterations */ |
1836 |
(PID.TID 0000.0001) 500 |
1837 |
(PID.TID 0000.0001) ; |
1838 |
(PID.TID 0000.0001) cg2dChkResFreq = /* 2d con. grad convergence test frequency */ |
1839 |
(PID.TID 0000.0001) 1 |
1840 |
(PID.TID 0000.0001) ; |
1841 |
(PID.TID 0000.0001) cg2dUseMinResSol= /* use cg2d last-iter(=0) / min-resid.(=1) solution */ |
1842 |
(PID.TID 0000.0001) 0 |
1843 |
(PID.TID 0000.0001) ; |
1844 |
(PID.TID 0000.0001) cg2dTargetResidual = /* 2d con. grad target residual */ |
1845 |
(PID.TID 0000.0001) 1.000000000000000E-12 |
1846 |
(PID.TID 0000.0001) ; |
1847 |
(PID.TID 0000.0001) cg2dTargetResWunit = /* CG2d target residual [W units] */ |
1848 |
(PID.TID 0000.0001) -1.000000000000000E+00 |
1849 |
(PID.TID 0000.0001) ; |
1850 |
(PID.TID 0000.0001) cg2dPreCondFreq = /* Freq. for updating cg2d preconditioner */ |
1851 |
(PID.TID 0000.0001) 1 |
1852 |
(PID.TID 0000.0001) ; |
1853 |
(PID.TID 0000.0001) useSRCGSolver = /* use single reduction CG solver(s) */ |
1854 |
(PID.TID 0000.0001) F |
1855 |
(PID.TID 0000.0001) ; |
1856 |
(PID.TID 0000.0001) printResidualFreq = /* Freq. for printing CG residual */ |
1857 |
(PID.TID 0000.0001) 0 |
1858 |
(PID.TID 0000.0001) ; |
1859 |
(PID.TID 0000.0001) // |
1860 |
(PID.TID 0000.0001) // Time stepping paramters ( PARM03 in namelist ) |
1861 |
(PID.TID 0000.0001) // |
1862 |
(PID.TID 0000.0001) deltaTMom = /* Momentum equation timestep ( s ) */ |
1863 |
(PID.TID 0000.0001) 1.800000000000000E+03 |
1864 |
(PID.TID 0000.0001) ; |
1865 |
(PID.TID 0000.0001) deltaTFreeSurf = /* FreeSurface equation timestep ( s ) */ |
1866 |
(PID.TID 0000.0001) 1.800000000000000E+03 |
1867 |
(PID.TID 0000.0001) ; |
1868 |
(PID.TID 0000.0001) dTtracerLev = /* Tracer equation timestep ( s ) */ |
1869 |
(PID.TID 0000.0001) 1.800000000000000E+03 /* K = 1 */ |
1870 |
(PID.TID 0000.0001) ; |
1871 |
(PID.TID 0000.0001) deltaTClock = /* Model clock timestep ( s ) */ |
1872 |
(PID.TID 0000.0001) 1.800000000000000E+03 |
1873 |
(PID.TID 0000.0001) ; |
1874 |
(PID.TID 0000.0001) cAdjFreq = /* Convective adjustment interval ( s ) */ |
1875 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1876 |
(PID.TID 0000.0001) ; |
1877 |
(PID.TID 0000.0001) momForcingOutAB = /* =1: take Momentum Forcing out of Adams-Bash. stepping */ |
1878 |
(PID.TID 0000.0001) 1 |
1879 |
(PID.TID 0000.0001) ; |
1880 |
(PID.TID 0000.0001) tracForcingOutAB = /* =1: take T,S,pTr Forcing out of Adams-Bash. stepping */ |
1881 |
(PID.TID 0000.0001) 1 |
1882 |
(PID.TID 0000.0001) ; |
1883 |
(PID.TID 0000.0001) momDissip_In_AB = /* put Dissipation Tendency in Adams-Bash. stepping */ |
1884 |
(PID.TID 0000.0001) T |
1885 |
(PID.TID 0000.0001) ; |
1886 |
(PID.TID 0000.0001) doAB_onGtGs = /* apply AB on Tendencies (rather than on T,S)*/ |
1887 |
(PID.TID 0000.0001) T |
1888 |
(PID.TID 0000.0001) ; |
1889 |
(PID.TID 0000.0001) abEps = /* Adams-Bashforth-2 stabilizing weight */ |
1890 |
(PID.TID 0000.0001) 1.000000000000000E-01 |
1891 |
(PID.TID 0000.0001) ; |
1892 |
(PID.TID 0000.0001) pickupStrictlyMatch= /* stop if pickup do not strictly match */ |
1893 |
(PID.TID 0000.0001) T |
1894 |
(PID.TID 0000.0001) ; |
1895 |
(PID.TID 0000.0001) nIter0 = /* Run starting timestep number */ |
1896 |
(PID.TID 0000.0001) 0 |
1897 |
(PID.TID 0000.0001) ; |
1898 |
(PID.TID 0000.0001) nTimeSteps = /* Number of timesteps */ |
1899 |
(PID.TID 0000.0001) 12 |
1900 |
(PID.TID 0000.0001) ; |
1901 |
(PID.TID 0000.0001) nEndIter = /* Run ending timestep number */ |
1902 |
(PID.TID 0000.0001) 12 |
1903 |
(PID.TID 0000.0001) ; |
1904 |
(PID.TID 0000.0001) baseTime = /* Model base time ( s ) */ |
1905 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1906 |
(PID.TID 0000.0001) ; |
1907 |
(PID.TID 0000.0001) startTime = /* Run start time ( s ) */ |
1908 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1909 |
(PID.TID 0000.0001) ; |
1910 |
(PID.TID 0000.0001) endTime = /* Integration ending time ( s ) */ |
1911 |
(PID.TID 0000.0001) 2.160000000000000E+04 |
1912 |
(PID.TID 0000.0001) ; |
1913 |
(PID.TID 0000.0001) pChkPtFreq = /* Permanent restart/pickup file interval ( s ) */ |
1914 |
(PID.TID 0000.0001) 3.600000000000000E+06 |
1915 |
(PID.TID 0000.0001) ; |
1916 |
(PID.TID 0000.0001) chkPtFreq = /* Rolling restart/pickup file interval ( s ) */ |
1917 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1918 |
(PID.TID 0000.0001) ; |
1919 |
(PID.TID 0000.0001) pickup_write_mdsio = /* Model IO flag. */ |
1920 |
(PID.TID 0000.0001) T |
1921 |
(PID.TID 0000.0001) ; |
1922 |
(PID.TID 0000.0001) pickup_read_mdsio = /* Model IO flag. */ |
1923 |
(PID.TID 0000.0001) T |
1924 |
(PID.TID 0000.0001) ; |
1925 |
(PID.TID 0000.0001) pickup_write_immed = /* Model IO flag. */ |
1926 |
(PID.TID 0000.0001) F |
1927 |
(PID.TID 0000.0001) ; |
1928 |
(PID.TID 0000.0001) writePickupAtEnd = /* Model IO flag. */ |
1929 |
(PID.TID 0000.0001) T |
1930 |
(PID.TID 0000.0001) ; |
1931 |
(PID.TID 0000.0001) dumpFreq = /* Model state write out interval ( s ). */ |
1932 |
(PID.TID 0000.0001) 4.320000000000000E+05 |
1933 |
(PID.TID 0000.0001) ; |
1934 |
(PID.TID 0000.0001) dumpInitAndLast= /* write out Initial & Last iter. model state */ |
1935 |
(PID.TID 0000.0001) T |
1936 |
(PID.TID 0000.0001) ; |
1937 |
(PID.TID 0000.0001) snapshot_mdsio = /* Model IO flag. */ |
1938 |
(PID.TID 0000.0001) T |
1939 |
(PID.TID 0000.0001) ; |
1940 |
(PID.TID 0000.0001) monitorFreq = /* Monitor output interval ( s ). */ |
1941 |
(PID.TID 0000.0001) 8.640000000000000E+05 |
1942 |
(PID.TID 0000.0001) ; |
1943 |
(PID.TID 0000.0001) monitorSelect = /* select group of variables to monitor */ |
1944 |
(PID.TID 0000.0001) 2 |
1945 |
(PID.TID 0000.0001) ; |
1946 |
(PID.TID 0000.0001) monitor_stdio = /* Model IO flag. */ |
1947 |
(PID.TID 0000.0001) T |
1948 |
(PID.TID 0000.0001) ; |
1949 |
(PID.TID 0000.0001) externForcingPeriod = /* forcing period (s) */ |
1950 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1951 |
(PID.TID 0000.0001) ; |
1952 |
(PID.TID 0000.0001) externForcingCycle = /* period of the cyle (s). */ |
1953 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1954 |
(PID.TID 0000.0001) ; |
1955 |
(PID.TID 0000.0001) tauThetaClimRelax = /* relaxation time scale (s) */ |
1956 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1957 |
(PID.TID 0000.0001) ; |
1958 |
(PID.TID 0000.0001) tauSaltClimRelax = /* relaxation time scale (s) */ |
1959 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1960 |
(PID.TID 0000.0001) ; |
1961 |
(PID.TID 0000.0001) latBandClimRelax = /* max. Lat. where relaxation */ |
1962 |
(PID.TID 0000.0001) 6.300000000000000E+05 |
1963 |
(PID.TID 0000.0001) ; |
1964 |
(PID.TID 0000.0001) // |
1965 |
(PID.TID 0000.0001) // Gridding paramters ( PARM04 in namelist ) |
1966 |
(PID.TID 0000.0001) // |
1967 |
(PID.TID 0000.0001) usingCartesianGrid = /* Cartesian coordinates flag ( True/False ) */ |
1968 |
(PID.TID 0000.0001) T |
1969 |
(PID.TID 0000.0001) ; |
1970 |
(PID.TID 0000.0001) usingCylindricalGrid = /* Cylindrical coordinates flag ( True/False ) */ |
1971 |
(PID.TID 0000.0001) F |
1972 |
(PID.TID 0000.0001) ; |
1973 |
(PID.TID 0000.0001) usingSphericalPolarGrid = /* Spherical coordinates flag ( True/False ) */ |
1974 |
(PID.TID 0000.0001) F |
1975 |
(PID.TID 0000.0001) ; |
1976 |
(PID.TID 0000.0001) usingCurvilinearGrid = /* Curvilinear coordinates flag ( True/False ) */ |
1977 |
(PID.TID 0000.0001) F |
1978 |
(PID.TID 0000.0001) ; |
1979 |
(PID.TID 0000.0001) selectSigmaCoord = /* Hybrid-Sigma Vert. Coordinate option */ |
1980 |
(PID.TID 0000.0001) 0 |
1981 |
(PID.TID 0000.0001) ; |
1982 |
(PID.TID 0000.0001) Ro_SeaLevel = /* r(1) ( units of r == m ) */ |
1983 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
1984 |
(PID.TID 0000.0001) ; |
1985 |
(PID.TID 0000.0001) rSigmaBnd = /* r/sigma transition ( units of r == m ) */ |
1986 |
(PID.TID 0000.0001) 1.234567000000000E+05 |
1987 |
(PID.TID 0000.0001) ; |
1988 |
(PID.TID 0000.0001) rkSign = /* index orientation relative to vertical coordinate */ |
1989 |
(PID.TID 0000.0001) -1.000000000000000E+00 |
1990 |
(PID.TID 0000.0001) ; |
1991 |
(PID.TID 0000.0001) gravitySign = /* gravity orientation relative to vertical coordinate */ |
1992 |
(PID.TID 0000.0001) -1.000000000000000E+00 |
1993 |
(PID.TID 0000.0001) ; |
1994 |
(PID.TID 0000.0001) mass2rUnit = /* convert mass per unit area [kg/m2] to r-units [m] */ |
1995 |
(PID.TID 0000.0001) 9.708737864077669E-04 |
1996 |
(PID.TID 0000.0001) ; |
1997 |
(PID.TID 0000.0001) rUnit2mass = /* convert r-units [m] to mass per unit area [kg/m2] */ |
1998 |
(PID.TID 0000.0001) 1.030000000000000E+03 |
1999 |
(PID.TID 0000.0001) ; |
2000 |
(PID.TID 0000.0001) drC = /* C spacing ( units of r ) */ |
2001 |
(PID.TID 0000.0001) 2 @ 5.000000000000000E+00 /* K = 1: 2 */ |
2002 |
(PID.TID 0000.0001) ; |
2003 |
(PID.TID 0000.0001) drF = /* W spacing ( units of r ) */ |
2004 |
(PID.TID 0000.0001) 1.000000000000000E+01 /* K = 1 */ |
2005 |
(PID.TID 0000.0001) ; |
2006 |
(PID.TID 0000.0001) delX = /* U spacing ( m - cartesian, degrees - spherical ) */ |
2007 |
(PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */ |
2008 |
(PID.TID 0000.0001) ; |
2009 |
(PID.TID 0000.0001) delY = /* V spacing ( m - cartesian, degrees - spherical ) */ |
2010 |
(PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */ |
2011 |
(PID.TID 0000.0001) ; |
2012 |
(PID.TID 0000.0001) xgOrigin = /* X-axis origin of West edge (cartesian: m, lat-lon: deg) */ |
2013 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
2014 |
(PID.TID 0000.0001) ; |
2015 |
(PID.TID 0000.0001) ygOrigin = /* Y-axis origin of South edge (cartesian: m, lat-lon: deg) */ |
2016 |
(PID.TID 0000.0001) -1.100000000000000E+05 |
2017 |
(PID.TID 0000.0001) ; |
2018 |
(PID.TID 0000.0001) rSphere = /* Radius ( ignored - cartesian, m - spherical ) */ |
2019 |
(PID.TID 0000.0001) 6.370000000000000E+06 |
2020 |
(PID.TID 0000.0001) ; |
2021 |
(PID.TID 0000.0001) deepAtmosphere = /* Deep/Shallow Atmosphere flag (True/False) */ |
2022 |
(PID.TID 0000.0001) F |
2023 |
(PID.TID 0000.0001) ; |
2024 |
(PID.TID 0000.0001) xC = /* xC(:,1,:,1) : P-point X coord ( deg. or m if cartesian) */ |
2025 |
(PID.TID 0000.0001) 2.500000000000000E+03, /* I = 1 */ |
2026 |
(PID.TID 0000.0001) 7.500000000000000E+03, /* I = 2 */ |
2027 |
(PID.TID 0000.0001) 1.250000000000000E+04, /* I = 3 */ |
2028 |
(PID.TID 0000.0001) . . . |
2029 |
(PID.TID 0000.0001) 8.750000000000000E+04, /* I = 18 */ |
2030 |
(PID.TID 0000.0001) 9.250000000000000E+04, /* I = 19 */ |
2031 |
(PID.TID 0000.0001) 9.750000000000000E+04, /* I = 20 */ |
2032 |
(PID.TID 0000.0001) 1.025000000000000E+05, /* I = 21 */ |
2033 |
(PID.TID 0000.0001) 1.075000000000000E+05, /* I = 22 */ |
2034 |
(PID.TID 0000.0001) 1.125000000000000E+05, /* I = 23 */ |
2035 |
(PID.TID 0000.0001) . . . |
2036 |
(PID.TID 0000.0001) 1.875000000000000E+05, /* I = 38 */ |
2037 |
(PID.TID 0000.0001) 1.925000000000000E+05, /* I = 39 */ |
2038 |
(PID.TID 0000.0001) 1.975000000000000E+05, /* I = 40 */ |
2039 |
(PID.TID 0000.0001) 2.025000000000000E+05, /* I = 41 */ |
2040 |
(PID.TID 0000.0001) 2.075000000000000E+05, /* I = 42 */ |
2041 |
(PID.TID 0000.0001) 2.125000000000000E+05, /* I = 43 */ |
2042 |
(PID.TID 0000.0001) . . . |
2043 |
(PID.TID 0000.0001) 2.875000000000000E+05, /* I = 58 */ |
2044 |
(PID.TID 0000.0001) 2.925000000000000E+05, /* I = 59 */ |
2045 |
(PID.TID 0000.0001) 2.975000000000000E+05, /* I = 60 */ |
2046 |
(PID.TID 0000.0001) 3.025000000000000E+05, /* I = 61 */ |
2047 |
(PID.TID 0000.0001) 3.075000000000000E+05, /* I = 62 */ |
2048 |
(PID.TID 0000.0001) 3.125000000000000E+05, /* I = 63 */ |
2049 |
(PID.TID 0000.0001) . . . |
2050 |
(PID.TID 0000.0001) 3.875000000000000E+05, /* I = 78 */ |
2051 |
(PID.TID 0000.0001) 3.925000000000000E+05, /* I = 79 */ |
2052 |
(PID.TID 0000.0001) 3.975000000000000E+05 /* I = 80 */ |
2053 |
(PID.TID 0000.0001) ; |
2054 |
(PID.TID 0000.0001) yC = /* yC(1,:,1,:) : P-point Y coord ( deg. or m if cartesian) */ |
2055 |
(PID.TID 0000.0001) -1.075000000000000E+05, /* J = 1 */ |
2056 |
(PID.TID 0000.0001) -1.025000000000000E+05, /* J = 2 */ |
2057 |
(PID.TID 0000.0001) -9.750000000000000E+04, /* J = 3 */ |
2058 |
(PID.TID 0000.0001) -9.250000000000000E+04, /* J = 4 */ |
2059 |
(PID.TID 0000.0001) -8.750000000000000E+04, /* J = 5 */ |
2060 |
(PID.TID 0000.0001) -8.250000000000000E+04, /* J = 6 */ |
2061 |
(PID.TID 0000.0001) -7.750000000000000E+04, /* J = 7 */ |
2062 |
(PID.TID 0000.0001) -7.250000000000000E+04, /* J = 8 */ |
2063 |
(PID.TID 0000.0001) -6.750000000000000E+04, /* J = 9 */ |
2064 |
(PID.TID 0000.0001) -6.250000000000000E+04, /* J = 10 */ |
2065 |
(PID.TID 0000.0001) -5.750000000000000E+04, /* J = 11 */ |
2066 |
(PID.TID 0000.0001) -5.250000000000000E+04, /* J = 12 */ |
2067 |
(PID.TID 0000.0001) -4.750000000000000E+04, /* J = 13 */ |
2068 |
(PID.TID 0000.0001) -4.250000000000000E+04, /* J = 14 */ |
2069 |
(PID.TID 0000.0001) -3.750000000000000E+04, /* J = 15 */ |
2070 |
(PID.TID 0000.0001) -3.250000000000000E+04, /* J = 16 */ |
2071 |
(PID.TID 0000.0001) -2.750000000000000E+04, /* J = 17 */ |
2072 |
(PID.TID 0000.0001) -2.250000000000000E+04, /* J = 18 */ |
2073 |
(PID.TID 0000.0001) -1.750000000000000E+04, /* J = 19 */ |
2074 |
(PID.TID 0000.0001) -1.250000000000000E+04, /* J = 20 */ |
2075 |
(PID.TID 0000.0001) -7.500000000000000E+03, /* J = 21 */ |
2076 |
(PID.TID 0000.0001) -2.500000000000000E+03, /* J = 22 */ |
2077 |
(PID.TID 0000.0001) 2.500000000000000E+03, /* J = 23 */ |
2078 |
(PID.TID 0000.0001) 7.500000000000000E+03, /* J = 24 */ |
2079 |
(PID.TID 0000.0001) 1.250000000000000E+04, /* J = 25 */ |
2080 |
(PID.TID 0000.0001) 1.750000000000000E+04, /* J = 26 */ |
2081 |
(PID.TID 0000.0001) 2.250000000000000E+04, /* J = 27 */ |
2082 |
(PID.TID 0000.0001) 2.750000000000000E+04, /* J = 28 */ |
2083 |
(PID.TID 0000.0001) 3.250000000000000E+04, /* J = 29 */ |
2084 |
(PID.TID 0000.0001) 3.750000000000000E+04, /* J = 30 */ |
2085 |
(PID.TID 0000.0001) 4.250000000000000E+04, /* J = 31 */ |
2086 |
(PID.TID 0000.0001) 4.750000000000000E+04, /* J = 32 */ |
2087 |
(PID.TID 0000.0001) 5.250000000000000E+04, /* J = 33 */ |
2088 |
(PID.TID 0000.0001) 5.750000000000000E+04, /* J = 34 */ |
2089 |
(PID.TID 0000.0001) 6.250000000000000E+04, /* J = 35 */ |
2090 |
(PID.TID 0000.0001) 6.750000000000000E+04, /* J = 36 */ |
2091 |
(PID.TID 0000.0001) 7.250000000000000E+04, /* J = 37 */ |
2092 |
(PID.TID 0000.0001) 7.750000000000000E+04, /* J = 38 */ |
2093 |
(PID.TID 0000.0001) 8.250000000000000E+04, /* J = 39 */ |
2094 |
(PID.TID 0000.0001) 8.750000000000000E+04, /* J = 40 */ |
2095 |
(PID.TID 0000.0001) 9.250000000000000E+04, /* J = 41 */ |
2096 |
(PID.TID 0000.0001) 9.750000000000000E+04 /* J = 42 */ |
2097 |
(PID.TID 0000.0001) ; |
2098 |
(PID.TID 0000.0001) rcoord = /* P-point R coordinate ( units of r ) */ |
2099 |
(PID.TID 0000.0001) -5.000000000000000E+00 /* K = 1 */ |
2100 |
(PID.TID 0000.0001) ; |
2101 |
(PID.TID 0000.0001) rF = /* W-Interf. R coordinate ( units of r ) */ |
2102 |
(PID.TID 0000.0001) 0.000000000000000E+00, /* K = 1 */ |
2103 |
(PID.TID 0000.0001) -1.000000000000000E+01 /* K = 2 */ |
2104 |
(PID.TID 0000.0001) ; |
2105 |
(PID.TID 0000.0001) deepFacC = /* deep-model grid factor @ cell-Center (-) */ |
2106 |
(PID.TID 0000.0001) 1.000000000000000E+00 /* K = 1 */ |
2107 |
(PID.TID 0000.0001) ; |
2108 |
(PID.TID 0000.0001) deepFacF = /* deep-model grid factor @ W-Interface (-) */ |
2109 |
(PID.TID 0000.0001) 2 @ 1.000000000000000E+00 /* K = 1: 2 */ |
2110 |
(PID.TID 0000.0001) ; |
2111 |
(PID.TID 0000.0001) rVel2wUnit = /* convert units: rVel -> wSpeed (=1 if z-coord)*/ |
2112 |
(PID.TID 0000.0001) 2 @ 1.000000000000000E+00 /* K = 1: 2 */ |
2113 |
(PID.TID 0000.0001) ; |
2114 |
(PID.TID 0000.0001) wUnit2rVel = /* convert units: wSpeed -> rVel (=1 if z-coord)*/ |
2115 |
(PID.TID 0000.0001) 2 @ 1.000000000000000E+00 /* K = 1: 2 */ |
2116 |
(PID.TID 0000.0001) ; |
2117 |
(PID.TID 0000.0001) dBdrRef = /* Vertical grad. of reference buoyancy [(m/s/r)^2] */ |
2118 |
(PID.TID 0000.0001) 0.000000000000000E+00 /* K = 1 */ |
2119 |
(PID.TID 0000.0001) ; |
2120 |
(PID.TID 0000.0001) rotateGrid = /* use rotated grid ( True/False ) */ |
2121 |
(PID.TID 0000.0001) F |
2122 |
(PID.TID 0000.0001) ; |
2123 |
(PID.TID 0000.0001) phiEuler = /* Euler angle, rotation about original z-coordinate [rad] */ |
2124 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
2125 |
(PID.TID 0000.0001) ; |
2126 |
(PID.TID 0000.0001) thetaEuler = /* Euler angle, rotation about new x-coordinate [rad] */ |
2127 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
2128 |
(PID.TID 0000.0001) ; |
2129 |
(PID.TID 0000.0001) psiEuler = /* Euler angle, rotation about new z-coordinate [rad] */ |
2130 |
(PID.TID 0000.0001) 0.000000000000000E+00 |
2131 |
(PID.TID 0000.0001) ; |
2132 |
(PID.TID 0000.0001) dxF = /* dxF(:,1,:,1) ( units: m ) */ |
2133 |
(PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */ |
2134 |
(PID.TID 0000.0001) ; |
2135 |
(PID.TID 0000.0001) dxF = /* dxF(1,:,1,:) ( units: m ) */ |
2136 |
(PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */ |
2137 |
(PID.TID 0000.0001) ; |
2138 |
(PID.TID 0000.0001) dyF = /* dyF(:,1,:,1) ( units: m ) */ |
2139 |
(PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */ |
2140 |
(PID.TID 0000.0001) ; |
2141 |
(PID.TID 0000.0001) dyF = /* dyF(1,:,1,:) ( units: m ) */ |
2142 |
(PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */ |
2143 |
(PID.TID 0000.0001) ; |
2144 |
(PID.TID 0000.0001) dxG = /* dxG(:,1,:,1) ( units: m ) */ |
2145 |
(PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */ |
2146 |
(PID.TID 0000.0001) ; |
2147 |
(PID.TID 0000.0001) dxG = /* dxG(1,:,1,:) ( units: m ) */ |
2148 |
(PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */ |
2149 |
(PID.TID 0000.0001) ; |
2150 |
(PID.TID 0000.0001) dyG = /* dyG(:,1,:,1) ( units: m ) */ |
2151 |
(PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */ |
2152 |
(PID.TID 0000.0001) ; |
2153 |
(PID.TID 0000.0001) dyG = /* dyG(1,:,1,:) ( units: m ) */ |
2154 |
(PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */ |
2155 |
(PID.TID 0000.0001) ; |
2156 |
(PID.TID 0000.0001) dxC = /* dxC(:,1,:,1) ( units: m ) */ |
2157 |
(PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */ |
2158 |
(PID.TID 0000.0001) ; |
2159 |
(PID.TID 0000.0001) dxC = /* dxC(1,:,1,:) ( units: m ) */ |
2160 |
(PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */ |
2161 |
(PID.TID 0000.0001) ; |
2162 |
(PID.TID 0000.0001) dyC = /* dyC(:,1,:,1) ( units: m ) */ |
2163 |
(PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */ |
2164 |
(PID.TID 0000.0001) ; |
2165 |
(PID.TID 0000.0001) dyC = /* dyC(1,:,1,:) ( units: m ) */ |
2166 |
(PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */ |
2167 |
(PID.TID 0000.0001) ; |
2168 |
(PID.TID 0000.0001) dxV = /* dxV(:,1,:,1) ( units: m ) */ |
2169 |
(PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */ |
2170 |
(PID.TID 0000.0001) ; |
2171 |
(PID.TID 0000.0001) dxV = /* dxV(1,:,1,:) ( units: m ) */ |
2172 |
(PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */ |
2173 |
(PID.TID 0000.0001) ; |
2174 |
(PID.TID 0000.0001) dyU = /* dyU(:,1,:,1) ( units: m ) */ |
2175 |
(PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */ |
2176 |
(PID.TID 0000.0001) ; |
2177 |
(PID.TID 0000.0001) dyU = /* dyU(1,:,1,:) ( units: m ) */ |
2178 |
(PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */ |
2179 |
(PID.TID 0000.0001) ; |
2180 |
(PID.TID 0000.0001) rA = /* rA (:,1,:,1) ( units: m^2 ) */ |
2181 |
(PID.TID 0000.0001) 80 @ 2.500000000000000E+07 /* I = 1: 80 */ |
2182 |
(PID.TID 0000.0001) ; |
2183 |
(PID.TID 0000.0001) rA = /* rA (1,:,1,:) ( units: m^2 ) */ |
2184 |
(PID.TID 0000.0001) 42 @ 2.500000000000000E+07 /* J = 1: 42 */ |
2185 |
(PID.TID 0000.0001) ; |
2186 |
(PID.TID 0000.0001) rAw = /* rAw(:,1,:,1) ( units: m^2 ) */ |
2187 |
(PID.TID 0000.0001) 80 @ 2.500000000000000E+07 /* I = 1: 80 */ |
2188 |
(PID.TID 0000.0001) ; |
2189 |
(PID.TID 0000.0001) rAw = /* rAw(1,:,1,:) ( units: m^2 ) */ |
2190 |
(PID.TID 0000.0001) 42 @ 2.500000000000000E+07 /* J = 1: 42 */ |
2191 |
(PID.TID 0000.0001) ; |
2192 |
(PID.TID 0000.0001) rAs = /* rAs(:,1,:,1) ( units: m^2 ) */ |
2193 |
(PID.TID 0000.0001) 80 @ 2.500000000000000E+07 /* I = 1: 80 */ |
2194 |
(PID.TID 0000.0001) ; |
2195 |
(PID.TID 0000.0001) rAs = /* rAs(1,:,1,:) ( units: m^2 ) */ |
2196 |
(PID.TID 0000.0001) 42 @ 2.500000000000000E+07 /* J = 1: 42 */ |
2197 |
(PID.TID 0000.0001) ; |
2198 |
(PID.TID 0000.0001) globalArea = /* Integrated horizontal Area (m^2) */ |
2199 |
(PID.TID 0000.0001) 6.950000000000000E+10 |
2200 |
(PID.TID 0000.0001) ; |
2201 |
(PID.TID 0000.0001) // ======================================================= |
2202 |
(PID.TID 0000.0001) // End of Model config. summary |
2203 |
(PID.TID 0000.0001) // ======================================================= |
2204 |
(PID.TID 0000.0001) |
2205 |
(PID.TID 0000.0001) == Packages configuration : Check & print summary == |
2206 |
(PID.TID 0000.0001) |
2207 |
(PID.TID 0000.0001) SEAICE_CHECK: #define ALLOW_SEAICE |
2208 |
(PID.TID 0000.0001) THSICE_CHECK: #define THSICE |
2209 |
(PID.TID 0000.0001) // ======================================================= |
2210 |
(PID.TID 0000.0001) // Check Model config. (CONFIG_CHECK): |
2211 |
(PID.TID 0000.0001) // CONFIG_CHECK : Normal End |
2212 |
(PID.TID 0000.0001) // ======================================================= |
2213 |
(PID.TID 0000.0001) |
2214 |
(PID.TID 0000.0001) MDS_READ_FIELD: opening global file: uVel_3c0.bin |
2215 |
(PID.TID 0000.0001) MDS_READ_FIELD: opening global file: vVel_3c0.bin |
2216 |
(PID.TID 0000.0001) MDS_READ_FIELD: opening global file: eta_3c0.bin |
2217 |
(PID.TID 0000.0001) Start initial hydrostatic pressure computation |
2218 |
(PID.TID 0000.0001) Pressure is predetermined for buoyancyRelation OCEANIC |
2219 |
(PID.TID 0000.0001) |
2220 |
(PID.TID 0000.0001) write diagnostics summary to file ioUnit: 6 |
2221 |
Iter.Nb: 0 ; Time(s): 0.0000000000000E+00 |
2222 |
------------------------------------------------------------------------ |
2223 |
2D/3D diagnostics: Number of lists: 1 |
2224 |
------------------------------------------------------------------------ |
2225 |
listId= 1 ; file name: snapshot |
2226 |
nFlds, nActive, freq & phase , nLev |
2227 |
5 | 5 | -86400.000000 3600.000000 | 1 |
2228 |
levels: 1 |
2229 |
diag# | name | ipt | iMate | kLev| count | mate.C| |
2230 |
153 |SIuice | 1 | 2 | 1 | 0 | 0 | |
2231 |
154 |SIvice | 2 | 1 | 1 | 0 | 0 | |
2232 |
147 |SIheff | 3 | 0 | 1 | 0 | |
2233 |
214 |SI_Fract| 4 | 0 | 1 | 0 | |
2234 |
215 |SI_Thick| 5 | 4 | 1 | 0 | 0 | |
2235 |
------------------------------------------------------------------------ |
2236 |
Global & Regional Statistics diagnostics: Number of lists: 1 |
2237 |
------------------------------------------------------------------------ |
2238 |
listId= 1 ; file name: iceStDiag |
2239 |
nFlds, nActive, freq & phase | |
2240 |
6 | 6 | 7200.000000 1800.000000 | |
2241 |
Regions: 0 |
2242 |
diag# | name | ipt | iMate | Volume | mate-Vol. | |
2243 |
214 |SI_Fract| 1 | 0 | 0.00000E+00 | |
2244 |
215 |SI_Thick| 2 | 1 | 0.00000E+00 | 0.00000E+00 | |
2245 |
144 |SIarea | 3 | 0 | 0.00000E+00 | |
2246 |
147 |SIheff | 4 | 0 | 0.00000E+00 | |
2247 |
153 |SIuice | 5 | 0 | 0.00000E+00 | |
2248 |
154 |SIvice | 6 | 0 | 0.00000E+00 | |
2249 |
------------------------------------------------------------------------ |
2250 |
(PID.TID 0000.0001) MDS_READ_FIELD: opening global file: windx.bin |
2251 |
(PID.TID 0000.0001) MDS_READ_FIELD: opening global file: const100.bin |
2252 |
(PID.TID 0000.0001) MDS_READ_FIELD: opening global file: const+20.bin |
2253 |
(PID.TID 0000.0001) // ======================================================= |
2254 |
(PID.TID 0000.0001) // Model current state |
2255 |
(PID.TID 0000.0001) // ======================================================= |
2256 |
(PID.TID 0000.0001) |
2257 |
(PID.TID 0000.0001) // ======================================================= |
2258 |
(PID.TID 0000.0001) // Begin MONITOR dynamic field statistics |
2259 |
(PID.TID 0000.0001) // ======================================================= |
2260 |
(PID.TID 0000.0001) %MON time_tsnumber = 0 |
2261 |
(PID.TID 0000.0001) %MON time_secondsf = 0.0000000000000E+00 |
2262 |
(PID.TID 0000.0001) %MON dynstat_eta_max = 1.4855271423662E-02 |
2263 |
(PID.TID 0000.0001) %MON dynstat_eta_min = -1.5547625271979E-02 |
2264 |
(PID.TID 0000.0001) %MON dynstat_eta_mean = -6.8609663050809E-19 |
2265 |
(PID.TID 0000.0001) %MON dynstat_eta_sd = 5.6185276903544E-03 |
2266 |
(PID.TID 0000.0001) %MON dynstat_eta_del2 = 3.4210904025025E-06 |
2267 |
(PID.TID 0000.0001) %MON dynstat_uvel_max = 5.4694595665363E-01 |
2268 |
(PID.TID 0000.0001) %MON dynstat_uvel_min = 8.1797628424127E-02 |
2269 |
(PID.TID 0000.0001) %MON dynstat_uvel_mean = 3.2603530929361E-01 |
2270 |
(PID.TID 0000.0001) %MON dynstat_uvel_sd = 8.4661197148990E-02 |
2271 |
(PID.TID 0000.0001) %MON dynstat_uvel_del2 = 1.3392731599312E-04 |
2272 |
(PID.TID 0000.0001) %MON dynstat_vvel_max = 2.2780617104059E-01 |
2273 |
(PID.TID 0000.0001) %MON dynstat_vvel_min = -1.4793000868950E-01 |
2274 |
(PID.TID 0000.0001) %MON dynstat_vvel_mean = -3.2450632095700E-04 |
2275 |
(PID.TID 0000.0001) %MON dynstat_vvel_sd = 6.0970835295293E-02 |
2276 |
(PID.TID 0000.0001) %MON dynstat_vvel_del2 = 8.1836652323282E-05 |
2277 |
(PID.TID 0000.0001) %MON dynstat_wvel_max = 1.6555698845343E-04 |
2278 |
(PID.TID 0000.0001) %MON dynstat_wvel_min = -2.4393468746960E-04 |
2279 |
(PID.TID 0000.0001) %MON dynstat_wvel_mean = -1.8006686469634E-21 |
2280 |
(PID.TID 0000.0001) %MON dynstat_wvel_sd = 1.8006622332191E-05 |
2281 |
(PID.TID 0000.0001) %MON dynstat_wvel_del2 = 3.4047422448573E-07 |
2282 |
(PID.TID 0000.0001) %MON dynstat_theta_max = -1.6200000000000E+00 |
2283 |
(PID.TID 0000.0001) %MON dynstat_theta_min = -1.6200000000000E+00 |
2284 |
(PID.TID 0000.0001) %MON dynstat_theta_mean = -1.6200000000000E+00 |
2285 |
(PID.TID 0000.0001) %MON dynstat_theta_sd = 0.0000000000000E+00 |
2286 |
(PID.TID 0000.0001) %MON dynstat_theta_del2 = 0.0000000000000E+00 |
2287 |
(PID.TID 0000.0001) %MON dynstat_salt_max = 3.0000000000000E+01 |
2288 |
(PID.TID 0000.0001) %MON dynstat_salt_min = 3.0000000000000E+01 |
2289 |
(PID.TID 0000.0001) %MON dynstat_salt_mean = 3.0000000000000E+01 |
2290 |
(PID.TID 0000.0001) %MON dynstat_salt_sd = 0.0000000000000E+00 |
2291 |
(PID.TID 0000.0001) %MON dynstat_salt_del2 = 0.0000000000000E+00 |
2292 |
(PID.TID 0000.0001) %MON advcfl_uvel_max = 1.9690054439531E-01 |
2293 |
(PID.TID 0000.0001) %MON advcfl_vvel_max = 8.2010221574612E-02 |
2294 |
(PID.TID 0000.0001) %MON advcfl_wvel_max = 8.7816487489057E-02 |
2295 |
(PID.TID 0000.0001) %MON advcfl_W_hf_max = 0.0000000000000E+00 |
2296 |
(PID.TID 0000.0001) %MON pe_b_mean = 1.5484032096270E-05 |
2297 |
(PID.TID 0000.0001) %MON ke_max = 1.4564487757410E-01 |
2298 |
(PID.TID 0000.0001) %MON ke_mean = 5.8130401708830E-02 |
2299 |
(PID.TID 0000.0001) %MON ke_vol = 6.9500000000000E+11 |
2300 |
(PID.TID 0000.0001) %MON vort_r_min = -1.4191202448594E-04 |
2301 |
(PID.TID 0000.0001) %MON vort_r_max = 8.9657385579761E-05 |
2302 |
(PID.TID 0000.0001) %MON vort_a_mean = -6.5586096803907E-22 |
2303 |
(PID.TID 0000.0001) %MON vort_a_sd = 1.5889649807104E-05 |
2304 |
(PID.TID 0000.0001) %MON vort_p_mean = -6.8228760045090E-22 |
2305 |
(PID.TID 0000.0001) %MON vort_p_sd = 3.0669223294758E-05 |
2306 |
(PID.TID 0000.0001) %MON surfExpan_theta_mean = -1.4394880171946E-21 |
2307 |
(PID.TID 0000.0001) %MON surfExpan_salt_mean = 1.6750406018264E-20 |
2308 |
(PID.TID 0000.0001) // ======================================================= |
2309 |
(PID.TID 0000.0001) // End MONITOR dynamic field statistics |
2310 |
(PID.TID 0000.0001) // ======================================================= |
2311 |
(PID.TID 0000.0001) // ======================================================= |
2312 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
2313 |
(PID.TID 0000.0001) // ======================================================= |
2314 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 0 |
2315 |
(PID.TID 0000.0001) %MON seaice_time_sec = 0.0000000000000E+00 |
2316 |
(PID.TID 0000.0001) %MON seaice_uice_max = 0.0000000000000E+00 |
2317 |
(PID.TID 0000.0001) %MON seaice_uice_min = 0.0000000000000E+00 |
2318 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 0.0000000000000E+00 |
2319 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 0.0000000000000E+00 |
2320 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 0.0000000000000E+00 |
2321 |
(PID.TID 0000.0001) %MON seaice_vice_max = 0.0000000000000E+00 |
2322 |
(PID.TID 0000.0001) %MON seaice_vice_min = 0.0000000000000E+00 |
2323 |
(PID.TID 0000.0001) %MON seaice_vice_mean = 0.0000000000000E+00 |
2324 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 0.0000000000000E+00 |
2325 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 0.0000000000000E+00 |
2326 |
(PID.TID 0000.0001) // ======================================================= |
2327 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
2328 |
(PID.TID 0000.0001) // ======================================================= |
2329 |
(PID.TID 0000.0001) // ======================================================= |
2330 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
2331 |
(PID.TID 0000.0001) // ======================================================= |
2332 |
(PID.TID 0000.0001) %MON thSI_time_sec = 0.0000000000000E+00 |
2333 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.9500000000000E+10 |
2334 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.9500000000000E+10 |
2335 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 4.0000000000000E+10 |
2336 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0000000000000E-01 |
2337 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0000000000000E-01 |
2338 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0000000000000E-01 |
2339 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 2.0000000000000E-01 |
2340 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0000000000000E-01 |
2341 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
2342 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
2343 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
2344 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
2345 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
2346 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
2347 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
2348 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
2349 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
2350 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
2351 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
2352 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
2353 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
2354 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
2355 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
2356 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
2357 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
2358 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
2359 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
2360 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
2361 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
2362 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
2363 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
2364 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
2365 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
2366 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
2367 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
2368 |
(PID.TID 0000.0001) // ======================================================= |
2369 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
2370 |
(PID.TID 0000.0001) // ======================================================= |
2371 |
(PID.TID 0000.0001) // ======================================================= |
2372 |
(PID.TID 0000.0001) // Begin MONITOR EXF statistics |
2373 |
(PID.TID 0000.0001) // ======================================================= |
2374 |
(PID.TID 0000.0001) %MON exf_tsnumber = 0 |
2375 |
(PID.TID 0000.0001) %MON exf_time_sec = 0.0000000000000E+00 |
2376 |
(PID.TID 0000.0001) %MON exf_ustress_max = 1.3964039188763E-01 |
2377 |
(PID.TID 0000.0001) %MON exf_ustress_min = 1.3964039188763E-01 |
2378 |
(PID.TID 0000.0001) %MON exf_ustress_mean = 1.3964039188763E-01 |
2379 |
(PID.TID 0000.0001) %MON exf_ustress_sd = 5.5511151231258E-17 |
2380 |
(PID.TID 0000.0001) %MON exf_ustress_del2 = 0.0000000000000E+00 |
2381 |
(PID.TID 0000.0001) %MON exf_vstress_max = 0.0000000000000E+00 |
2382 |
(PID.TID 0000.0001) %MON exf_vstress_min = 0.0000000000000E+00 |
2383 |
(PID.TID 0000.0001) %MON exf_vstress_mean = 0.0000000000000E+00 |
2384 |
(PID.TID 0000.0001) %MON exf_vstress_sd = 0.0000000000000E+00 |
2385 |
(PID.TID 0000.0001) %MON exf_vstress_del2 = 0.0000000000000E+00 |
2386 |
(PID.TID 0000.0001) %MON exf_hflux_max = 1.3256147102117E+02 |
2387 |
(PID.TID 0000.0001) %MON exf_hflux_min = 1.3256147102117E+02 |
2388 |
(PID.TID 0000.0001) %MON exf_hflux_mean = 1.3256147102117E+02 |
2389 |
(PID.TID 0000.0001) %MON exf_hflux_sd = 9.6633812063374E-13 |
2390 |
(PID.TID 0000.0001) %MON exf_hflux_del2 = 7.8352778346434E-01 |
2391 |
(PID.TID 0000.0001) %MON exf_sflux_max = 5.8259080752307E-08 |
2392 |
(PID.TID 0000.0001) %MON exf_sflux_min = 5.8259080752307E-08 |
2393 |
(PID.TID 0000.0001) %MON exf_sflux_mean = 5.8259080752308E-08 |
2394 |
(PID.TID 0000.0001) %MON exf_sflux_sd = 8.7350272685600E-22 |
2395 |
(PID.TID 0000.0001) %MON exf_sflux_del2 = 3.4435049684410E-10 |
2396 |
(PID.TID 0000.0001) %MON exf_uwind_max = 1.0000000000000E+01 |
2397 |
(PID.TID 0000.0001) %MON exf_uwind_min = 1.0000000000000E+01 |
2398 |
(PID.TID 0000.0001) %MON exf_uwind_mean = 1.0000000000000E+01 |
2399 |
(PID.TID 0000.0001) %MON exf_uwind_sd = 0.0000000000000E+00 |
2400 |
(PID.TID 0000.0001) %MON exf_uwind_del2 = 5.9106750809910E-02 |
2401 |
(PID.TID 0000.0001) %MON exf_vwind_max = 0.0000000000000E+00 |
2402 |
(PID.TID 0000.0001) %MON exf_vwind_min = 0.0000000000000E+00 |
2403 |
(PID.TID 0000.0001) %MON exf_vwind_mean = 0.0000000000000E+00 |
2404 |
(PID.TID 0000.0001) %MON exf_vwind_sd = 0.0000000000000E+00 |
2405 |
(PID.TID 0000.0001) %MON exf_vwind_del2 = 0.0000000000000E+00 |
2406 |
(PID.TID 0000.0001) %MON exf_wspeed_max = 1.0000000000000E+01 |
2407 |
(PID.TID 0000.0001) %MON exf_wspeed_min = 1.0000000000000E+01 |
2408 |
(PID.TID 0000.0001) %MON exf_wspeed_mean = 1.0000000000000E+01 |
2409 |
(PID.TID 0000.0001) %MON exf_wspeed_sd = 0.0000000000000E+00 |
2410 |
(PID.TID 0000.0001) %MON exf_wspeed_del2 = 5.9106750809910E-02 |
2411 |
(PID.TID 0000.0001) %MON exf_evap_max = 5.8259080752307E-08 |
2412 |
(PID.TID 0000.0001) %MON exf_evap_min = 5.8259080752307E-08 |
2413 |
(PID.TID 0000.0001) %MON exf_evap_mean = 5.8259080752308E-08 |
2414 |
(PID.TID 0000.0001) %MON exf_evap_sd = 8.7350272685600E-22 |
2415 |
(PID.TID 0000.0001) %MON exf_evap_del2 = 3.4435049684410E-10 |
2416 |
(PID.TID 0000.0001) // ======================================================= |
2417 |
(PID.TID 0000.0001) // End MONITOR EXF statistics |
2418 |
(PID.TID 0000.0001) // ======================================================= |
2419 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 1 0.99000E+00 0.91213E+00 |
2420 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 1, Nb. of FGMRES iterations = 2 |
2421 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 2 0.99000E+00 0.90517E+00 |
2422 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 2, Nb. of FGMRES iterations = 4 |
2423 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 3 0.99000E+00 0.89130E+00 |
2424 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 3, Nb. of FGMRES iterations = 3 |
2425 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 4 0.99000E+00 0.86558E+00 |
2426 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 4, Nb. of FGMRES iterations = 1 |
2427 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 5 0.99000E+00 0.84841E+00 |
2428 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 5, Nb. of FGMRES iterations = 1 |
2429 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 6 0.99000E+00 0.82430E+00 |
2430 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 6, Nb. of FGMRES iterations = 1 |
2431 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 7 0.99000E+00 0.76050E+00 |
2432 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 7, Nb. of FGMRES iterations = 1 |
2433 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 8 0.99000E+00 0.58237E+00 |
2434 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 8, Nb. of FGMRES iterations = 1 |
2435 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 9 0.55157E+00 0.39168E+00 |
2436 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 9, Nb. of FGMRES iterations = 2 |
2437 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 10 0.65139E+00 0.29433E+00 |
2438 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 10, Nb. of FGMRES iterations = 3 |
2439 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 10 1 0.10000E+01 0.29433E+00 0.51474E+00 |
2440 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 10 2-0.50000E+00 0.29433E+00 0.29643E+00 |
2441 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 11 0.90244E+00 0.27486E+00 |
2442 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 11, Nb. of FGMRES iterations = 2 |
2443 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 12 0.81118E+00 0.23907E+00 |
2444 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 12, Nb. of FGMRES iterations = 1 |
2445 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 13 13 0.35012E+00 0.11876E+00 |
2446 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 13 / 13, Nb. of FGMRES iterations = 4 |
2447 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 13 1 0.10000E+01 0.11876E+00 0.18893E+00 |
2448 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 13 2-0.50000E+00 0.11876E+00 0.15786E+00 |
2449 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 14 14 0.93001E+00 0.11315E+00 |
2450 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 14 / 14, Nb. of FGMRES iterations = 1 |
2451 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 15 15 0.44498E+00 0.65950E-01 |
2452 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 15 / 15, Nb. of FGMRES iterations = 4 |
2453 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 15 1 0.10000E+01 0.65950E-01 0.12808E+00 |
2454 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 15 2-0.50000E+00 0.65950E-01 0.10396E+00 |
2455 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 15 3-0.25000E+00 0.65950E-01 0.76871E-01 |
2456 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 16 16 0.90262E+00 0.61596E-01 |
2457 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 16 / 16, Nb. of FGMRES iterations = 2 |
2458 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 16 1 0.10000E+01 0.61596E-01 0.84605E-01 |
2459 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 17 17 0.97164E+00 0.60426E-01 |
2460 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 17 / 17, Nb. of FGMRES iterations = 1 |
2461 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 18 18 0.78581E+00 0.51456E-01 |
2462 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 18 / 18, Nb. of FGMRES iterations = 4 |
2463 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 18 1 0.10000E+01 0.51456E-01 0.94708E-01 |
2464 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 18 2-0.50000E+00 0.51456E-01 0.70320E-01 |
2465 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 19 19 0.90123E+00 0.48009E-01 |
2466 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 19 / 19, Nb. of FGMRES iterations = 2 |
2467 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 20 20 0.96726E+00 0.46956E-01 |
2468 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 20 / 20, Nb. of FGMRES iterations = 1 |
2469 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 21 21 0.88015E+00 0.43125E-01 |
2470 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 21 / 21, Nb. of FGMRES iterations = 3 |
2471 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 21 1 0.10000E+01 0.43125E-01 0.43569E-01 |
2472 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 22 22 0.87857E+00 0.39559E-01 |
2473 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 22 / 22, Nb. of FGMRES iterations = 3 |
2474 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 22 1 0.10000E+01 0.39559E-01 0.50743E-01 |
2475 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 22 2-0.50000E+00 0.39559E-01 0.40625E-01 |
2476 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 23 23 0.99000E+00 0.39389E-01 |
2477 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 23 / 23, Nb. of FGMRES iterations = 1 |
2478 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 24 24 0.97460E+00 0.38719E-01 |
2479 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 24 / 24, Nb. of FGMRES iterations = 3 |
2480 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 24 1 0.10000E+01 0.38719E-01 0.49904E-01 |
2481 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 25 25 0.96192E+00 0.37730E-01 |
2482 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 25 / 25, Nb. of FGMRES iterations = 1 |
2483 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 26 26 0.91449E+00 0.35547E-01 |
2484 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 26 / 26, Nb. of FGMRES iterations = 3 |
2485 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 26 1 0.10000E+01 0.35547E-01 0.88702E-01 |
2486 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 26 2-0.50000E+00 0.35547E-01 0.52210E-01 |
2487 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 27 27 0.87133E+00 0.32428E-01 |
2488 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 27 / 27, Nb. of FGMRES iterations = 3 |
2489 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 27 1 0.10000E+01 0.32428E-01 0.44979E-01 |
2490 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 28 28 0.84552E+00 0.28996E-01 |
2491 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 28 / 28, Nb. of FGMRES iterations = 3 |
2492 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 28 1 0.10000E+01 0.28996E-01 0.57513E-01 |
2493 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 28 2-0.50000E+00 0.28996E-01 0.33259E-01 |
2494 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 29 29 0.90227E+00 0.27075E-01 |
2495 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 29 / 29, Nb. of FGMRES iterations = 3 |
2496 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 29 1 0.10000E+01 0.27075E-01 0.44575E-01 |
2497 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 30 30 0.95228E+00 0.26207E-01 |
2498 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 30 / 30, Nb. of FGMRES iterations = 1 |
2499 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 31 31 0.92182E+00 0.24822E-01 |
2500 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 31 / 31, Nb. of FGMRES iterations = 3 |
2501 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 31 1 0.10000E+01 0.24822E-01 0.76986E-01 |
2502 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 31 2-0.50000E+00 0.24822E-01 0.45405E-01 |
2503 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 32 32 0.86653E+00 0.22561E-01 |
2504 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 32 / 32, Nb. of FGMRES iterations = 4 |
2505 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 32 1 0.10000E+01 0.22561E-01 0.75443E-01 |
2506 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 32 2-0.50000E+00 0.22561E-01 0.46480E-01 |
2507 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 33 33 0.96350E+00 0.22009E-01 |
2508 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 33 / 33, Nb. of FGMRES iterations = 1 |
2509 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 34 34 0.72122E+00 0.17700E-01 |
2510 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 34 / 34, Nb. of FGMRES iterations = 4 |
2511 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 34 1 0.10000E+01 0.17700E-01 0.73356E-01 |
2512 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 34 2-0.50000E+00 0.17700E-01 0.19915E-01 |
2513 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 35 35 0.79217E+00 0.15154E-01 |
2514 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 35 / 35, Nb. of FGMRES iterations = 4 |
2515 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 35 1 0.10000E+01 0.15154E-01 0.22294E-01 |
2516 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 36 36 0.76798E+00 0.12708E-01 |
2517 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 36 / 36, Nb. of FGMRES iterations = 5 |
2518 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 36 1 0.10000E+01 0.12708E-01 0.30233E-01 |
2519 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 37 37 0.70341E+00 0.10051E-01 |
2520 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 37 / 37, Nb. of FGMRES iterations = 5 |
2521 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 37 1 0.10000E+01 0.10051E-01 0.10197E-01 |
2522 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 38 38 0.72647E+00 0.81227E-02 |
2523 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 38 / 38, Nb. of FGMRES iterations = 5 |
2524 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 39 39 0.81841E+00 0.71070E-02 |
2525 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 39 / 39, Nb. of FGMRES iterations = 1 |
2526 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 40 40 0.57780E+00 0.49302E-02 |
2527 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 40 / 40, Nb. of FGMRES iterations = 7 |
2528 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 41 41 0.47660E+00 0.30082E-02 |
2529 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 41 / 41, Nb. of FGMRES iterations = 9 |
2530 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 42 42 0.79335E+00 0.25780E-02 |
2531 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 42 / 42, Nb. of FGMRES iterations = 1 |
2532 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 43 43 0.56221E+00 0.17561E-02 |
2533 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 43 / 43, Nb. of FGMRES iterations = 5 |
2534 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 44 44 0.41124E+00 0.97112E-03 |
2535 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 44 / 44, Nb. of FGMRES iterations = 10 |
2536 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 45 45 0.27962E+00 0.41526E-03 |
2537 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 45 / 45, Nb. of FGMRES iterations = 12 |
2538 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 46 46 0.14886E+00 0.11664E-03 |
2539 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 46 / 46, Nb. of FGMRES iterations = 15 |
2540 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 47 47 0.10000E+00 0.15415E-04 |
2541 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 47 / 47, Nb. of FGMRES iterations = 19 |
2542 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 48 48 0.10000E+00 0.15183E-05 |
2543 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 48 / 48, Nb. of FGMRES iterations = 20 |
2544 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 49 49 0.10000E+00 0.13517E-06 |
2545 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 49 / 49, Nb. of FGMRES iterations = 19 |
2546 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 50 50 0.10000E+00 0.13157E-07 |
2547 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 50 / 50, Nb. of FGMRES iterations = 21 |
2548 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 51 51 0.10000E+00 0.11773E-08 |
2549 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 51 / 51, Nb. of FGMRES iterations = 21 |
2550 |
(PID.TID 0000.0001) // ======================================================= |
2551 |
(PID.TID 0000.0001) // Begin JFNK statistics |
2552 |
(PID.TID 0000.0001) // ======================================================= |
2553 |
(PID.TID 0000.0001) %JFNK_MON: time step = 1 |
2554 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
2555 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 52 |
2556 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 256 |
2557 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
2558 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
2559 |
(PID.TID 0000.0001) // ======================================================= |
2560 |
(PID.TID 0000.0001) // End JFNK statistics |
2561 |
(PID.TID 0000.0001) // ======================================================= |
2562 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 256 in timestep 1 |
2563 |
(PID.TID 0000.0001) // ======================================================= |
2564 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
2565 |
(PID.TID 0000.0001) // ======================================================= |
2566 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 1 |
2567 |
(PID.TID 0000.0001) %MON seaice_time_sec = 1.8000000000000E+03 |
2568 |
(PID.TID 0000.0001) %MON seaice_uice_max = 6.4816187447188E-01 |
2569 |
(PID.TID 0000.0001) %MON seaice_uice_min = 3.0300019015468E-01 |
2570 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.0874070097997E-01 |
2571 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 7.3259575922821E-02 |
2572 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 6.3141827965965E-05 |
2573 |
(PID.TID 0000.0001) %MON seaice_vice_max = 1.2130119036920E-01 |
2574 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.0358180142910E-01 |
2575 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -7.0273686083667E-04 |
2576 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 4.4541964911875E-02 |
2577 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 3.4677486790705E-05 |
2578 |
(PID.TID 0000.0001) // ======================================================= |
2579 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
2580 |
(PID.TID 0000.0001) // ======================================================= |
2581 |
(PID.TID 0000.0001) // ======================================================= |
2582 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
2583 |
(PID.TID 0000.0001) // ======================================================= |
2584 |
(PID.TID 0000.0001) %MON thSI_time_sec = 1.8000000000000E+03 |
2585 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.9435140622619E+10 |
2586 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.9438496332228E+10 |
2587 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9996644290390E+10 |
2588 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0018682003608E-01 |
2589 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0041663963418E-01 |
2590 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0001766726049E-01 |
2591 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 2.2797689207382E-01 |
2592 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0012237212588E-01 |
2593 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
2594 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
2595 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
2596 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
2597 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
2598 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
2599 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
2600 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
2601 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
2602 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
2603 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
2604 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
2605 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
2606 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
2607 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
2608 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
2609 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
2610 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
2611 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
2612 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
2613 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
2614 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
2615 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
2616 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
2617 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
2618 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
2619 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
2620 |
(PID.TID 0000.0001) // ======================================================= |
2621 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
2622 |
(PID.TID 0000.0001) // ======================================================= |
2623 |
Compute Stats, Diag. # 214 SI_Fract vol( 0 ): 6.950E+10 Parms: SM P M1 |
2624 |
Compute Stats, Diag. # 215 SI_Thick vol( 0 ): 6.950E+10 Parms: SM PC M1 |
2625 |
use Counter Mate # 214 SI_Fract vol( 0 ): 6.950E+10 integral 6.950E+10 |
2626 |
Compute Stats, Diag. # 144 SIarea vol( 0 ): 6.950E+10 Parms: SM M1 |
2627 |
Compute Stats, Diag. # 147 SIheff vol( 0 ): 6.950E+10 Parms: SM M1 |
2628 |
Compute Stats, Diag. # 153 SIuice vol( 0 ): 6.900E+10 Parms: UU M1 |
2629 |
Compute Stats, Diag. # 154 SIvice vol( 0 ): 6.750E+10 Parms: VV M1 |
2630 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 201 0.99000E+00 0.56173E-01 |
2631 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 201, Nb. of FGMRES iterations = 1 |
2632 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 202 0.99000E+00 0.53439E-01 |
2633 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 202, Nb. of FGMRES iterations = 2 |
2634 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 2 1 0.10000E+01 0.53439E-01 0.53473E-01 |
2635 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 203 0.99000E+00 0.51993E-01 |
2636 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 203, Nb. of FGMRES iterations = 2 |
2637 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 204 0.99000E+00 0.51516E-01 |
2638 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 204, Nb. of FGMRES iterations = 3 |
2639 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 4 1 0.10000E+01 0.51516E-01 0.55659E-01 |
2640 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 205 0.99000E+00 0.50799E-01 |
2641 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 205, Nb. of FGMRES iterations = 3 |
2642 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 5 1 0.10000E+01 0.50799E-01 0.54281E-01 |
2643 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 206 0.99000E+00 0.50119E-01 |
2644 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 206, Nb. of FGMRES iterations = 3 |
2645 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 6 1 0.10000E+01 0.50119E-01 0.57158E-01 |
2646 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 6 2-0.50000E+00 0.50119E-01 0.51123E-01 |
2647 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 207 0.99000E+00 0.49358E-01 |
2648 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 207, Nb. of FGMRES iterations = 3 |
2649 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 7 1 0.10000E+01 0.49358E-01 0.55228E-01 |
2650 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 208 0.99000E+00 0.49223E-01 |
2651 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 208, Nb. of FGMRES iterations = 3 |
2652 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 209 0.99000E+00 0.49000E-01 |
2653 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 209, Nb. of FGMRES iterations = 3 |
2654 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 210 0.99000E+00 0.48198E-01 |
2655 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 210, Nb. of FGMRES iterations = 3 |
2656 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 211 0.99000E+00 0.47299E-01 |
2657 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 211, Nb. of FGMRES iterations = 3 |
2658 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 11 1 0.10000E+01 0.47299E-01 0.47446E-01 |
2659 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 212 0.99000E+00 0.46363E-01 |
2660 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 212, Nb. of FGMRES iterations = 4 |
2661 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 13 213 0.99000E+00 0.43339E-01 |
2662 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 13 / 213, Nb. of FGMRES iterations = 3 |
2663 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 13 1 0.10000E+01 0.43339E-01 0.46072E-01 |
2664 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 14 214 0.99000E+00 0.41647E-01 |
2665 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 14 / 214, Nb. of FGMRES iterations = 3 |
2666 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 14 1 0.10000E+01 0.41647E-01 0.69586E-01 |
2667 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 15 215 0.99000E+00 0.41301E-01 |
2668 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 15 / 215, Nb. of FGMRES iterations = 2 |
2669 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 16 216 0.99000E+00 0.40381E-01 |
2670 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 16 / 216, Nb. of FGMRES iterations = 2 |
2671 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 17 217 0.99000E+00 0.39104E-01 |
2672 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 17 / 217, Nb. of FGMRES iterations = 2 |
2673 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 18 218 0.99000E+00 0.38205E-01 |
2674 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 18 / 218, Nb. of FGMRES iterations = 3 |
2675 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 19 219 0.99000E+00 0.38041E-01 |
2676 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 19 / 219, Nb. of FGMRES iterations = 1 |
2677 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 20 220 0.99000E+00 0.37645E-01 |
2678 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 20 / 220, Nb. of FGMRES iterations = 2 |
2679 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 21 221 0.99000E+00 0.36922E-01 |
2680 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 21 / 221, Nb. of FGMRES iterations = 2 |
2681 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 22 222 0.99000E+00 0.36509E-01 |
2682 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 22 / 222, Nb. of FGMRES iterations = 2 |
2683 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 23 223 0.99000E+00 0.35846E-01 |
2684 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 23 / 223, Nb. of FGMRES iterations = 3 |
2685 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 23 1 0.10000E+01 0.35846E-01 0.65254E-01 |
2686 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 23 2-0.50000E+00 0.35846E-01 0.37446E-01 |
2687 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 24 224 0.99000E+00 0.33000E-01 |
2688 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 24 / 224, Nb. of FGMRES iterations = 1 |
2689 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 25 225 0.99000E+00 0.32159E-01 |
2690 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 25 / 225, Nb. of FGMRES iterations = 2 |
2691 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 26 226 0.99000E+00 0.30841E-01 |
2692 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 26 / 226, Nb. of FGMRES iterations = 1 |
2693 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 27 227 0.99000E+00 0.28609E-01 |
2694 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 27 / 227, Nb. of FGMRES iterations = 1 |
2695 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 28 228 0.95898E+00 0.27821E-01 |
2696 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 28 / 228, Nb. of FGMRES iterations = 1 |
2697 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 29 229 0.88433E+00 0.25632E-01 |
2698 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 29 / 229, Nb. of FGMRES iterations = 2 |
2699 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 29 1 0.10000E+01 0.25632E-01 0.69681E-01 |
2700 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 29 2-0.50000E+00 0.25632E-01 0.33069E-01 |
2701 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 30 230 0.77406E+00 0.21609E-01 |
2702 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 30 / 230, Nb. of FGMRES iterations = 4 |
2703 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 30 1 0.10000E+01 0.21609E-01 0.69223E-01 |
2704 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 30 2-0.50000E+00 0.21609E-01 0.49397E-01 |
2705 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 31 231 0.87252E+00 0.19731E-01 |
2706 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 31 / 231, Nb. of FGMRES iterations = 1 |
2707 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 32 232 0.64519E+00 0.14732E-01 |
2708 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 32 / 232, Nb. of FGMRES iterations = 5 |
2709 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 32 1 0.10000E+01 0.14732E-01 0.73418E-01 |
2710 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 32 2-0.50000E+00 0.14732E-01 0.43872E-01 |
2711 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 33 233 0.76113E+00 0.12281E-01 |
2712 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 33 / 233, Nb. of FGMRES iterations = 4 |
2713 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 33 1 0.10000E+01 0.12281E-01 0.38569E-01 |
2714 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 34 234 0.71025E+00 0.97766E-02 |
2715 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 34 / 234, Nb. of FGMRES iterations = 5 |
2716 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 34 1 0.10000E+01 0.97766E-02 0.48485E-01 |
2717 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 35 235 0.63986E+00 0.72596E-02 |
2718 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 35 / 235, Nb. of FGMRES iterations = 6 |
2719 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 35 1 0.10000E+01 0.72596E-02 0.16932E-01 |
2720 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 36 236 0.59134E+00 0.51145E-02 |
2721 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 36 / 236, Nb. of FGMRES iterations = 7 |
2722 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 36 1 0.10000E+01 0.51145E-02 0.29001E-01 |
2723 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 37 237 0.64547E+00 0.38199E-02 |
2724 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 37 / 237, Nb. of FGMRES iterations = 6 |
2725 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 38 238 0.50029E+00 0.24073E-02 |
2726 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 38 / 238, Nb. of FGMRES iterations = 9 |
2727 |
(PID.TID 0000.0001) S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc = 38 1 0.10000E+01 0.24073E-02 0.85685E-02 |
2728 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 39 239 0.54702E+00 0.16102E-02 |
2729 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 39 / 239, Nb. of FGMRES iterations = 7 |
2730 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 40 240 0.40304E+00 0.87856E-03 |
2731 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 40 / 240, Nb. of FGMRES iterations = 10 |
2732 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 41 241 0.48510E+00 0.54241E-03 |
2733 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 41 / 241, Nb. of FGMRES iterations = 3 |
2734 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 42 242 0.28736E+00 0.23620E-03 |
2735 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 42 / 242, Nb. of FGMRES iterations = 11 |
2736 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 43 243 0.12221E+00 0.58168E-04 |
2737 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 43 / 243, Nb. of FGMRES iterations = 16 |
2738 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 44 244 0.10000E+00 0.63463E-05 |
2739 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 44 / 244, Nb. of FGMRES iterations = 17 |
2740 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 45 245 0.10000E+00 0.54907E-06 |
2741 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 45 / 245, Nb. of FGMRES iterations = 18 |
2742 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 46 246 0.10000E+00 0.43331E-07 |
2743 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 46 / 246, Nb. of FGMRES iterations = 18 |
2744 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 47 247 0.10000E+00 0.41942E-08 |
2745 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 47 / 247, Nb. of FGMRES iterations = 18 |
2746 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 48 248 0.10000E+00 0.38787E-09 |
2747 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 48 / 248, Nb. of FGMRES iterations = 19 |
2748 |
(PID.TID 0000.0001) // ======================================================= |
2749 |
(PID.TID 0000.0001) // Begin JFNK statistics |
2750 |
(PID.TID 0000.0001) // ======================================================= |
2751 |
(PID.TID 0000.0001) %JFNK_MON: time step = 2 |
2752 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
2753 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 49 |
2754 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 250 |
2755 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
2756 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
2757 |
(PID.TID 0000.0001) // ======================================================= |
2758 |
(PID.TID 0000.0001) // End JFNK statistics |
2759 |
(PID.TID 0000.0001) // ======================================================= |
2760 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 250 in timestep 2 |
2761 |
(PID.TID 0000.0001) // ======================================================= |
2762 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
2763 |
(PID.TID 0000.0001) // ======================================================= |
2764 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 2 |
2765 |
(PID.TID 0000.0001) %MON seaice_time_sec = 3.6000000000000E+03 |
2766 |
(PID.TID 0000.0001) %MON seaice_uice_max = 6.9218916328781E-01 |
2767 |
(PID.TID 0000.0001) %MON seaice_uice_min = 3.1952670176038E-01 |
2768 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3262176925323E-01 |
2769 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 7.8434465328448E-02 |
2770 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 7.5559013624586E-05 |
2771 |
(PID.TID 0000.0001) %MON seaice_vice_max = 1.4518920902620E-01 |
2772 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.2472689331798E-01 |
2773 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -1.5035419355394E-03 |
2774 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.2307487244215E-02 |
2775 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 4.5930926886342E-05 |
2776 |
(PID.TID 0000.0001) // ======================================================= |
2777 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
2778 |
(PID.TID 0000.0001) // ======================================================= |
2779 |
(PID.TID 0000.0001) // ======================================================= |
2780 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
2781 |
(PID.TID 0000.0001) // ======================================================= |
2782 |
(PID.TID 0000.0001) %MON thSI_time_sec = 3.6000000000000E+03 |
2783 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.9369945264240E+10 |
2784 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.9376760896335E+10 |
2785 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9993184367905E+10 |
2786 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0037495989154E-01 |
2787 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0083976004582E-01 |
2788 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0003354364242E-01 |
2789 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 2.5248085304603E-01 |
2790 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0023507835377E-01 |
2791 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
2792 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
2793 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
2794 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
2795 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
2796 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
2797 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
2798 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
2799 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
2800 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
2801 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
2802 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
2803 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
2804 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
2805 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
2806 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
2807 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
2808 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
2809 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
2810 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
2811 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
2812 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
2813 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
2814 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
2815 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
2816 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
2817 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
2818 |
(PID.TID 0000.0001) // ======================================================= |
2819 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
2820 |
(PID.TID 0000.0001) // ======================================================= |
2821 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 401 0.99000E+00 0.11191E-01 |
2822 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 401, Nb. of FGMRES iterations = 1 |
2823 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 402 0.99000E+00 0.84827E-02 |
2824 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 402, Nb. of FGMRES iterations = 1 |
2825 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 403 0.99000E+00 0.74349E-02 |
2826 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 403, Nb. of FGMRES iterations = 1 |
2827 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 404 0.99000E+00 0.65011E-02 |
2828 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 404, Nb. of FGMRES iterations = 1 |
2829 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 405 0.99000E+00 0.55961E-02 |
2830 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 405, Nb. of FGMRES iterations = 1 |
2831 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 406 0.90158E+00 0.52226E-02 |
2832 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 406, Nb. of FGMRES iterations = 1 |
2833 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 407 0.84119E+00 0.46539E-02 |
2834 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 407, Nb. of FGMRES iterations = 2 |
2835 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 408 0.53342E+00 0.30610E-02 |
2836 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 408, Nb. of FGMRES iterations = 8 |
2837 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 409 0.83704E+00 0.27187E-02 |
2838 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 409, Nb. of FGMRES iterations = 1 |
2839 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 410 0.65031E+00 0.20407E-02 |
2840 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 410, Nb. of FGMRES iterations = 5 |
2841 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 411 0.50365E+00 0.12918E-02 |
2842 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 411, Nb. of FGMRES iterations = 7 |
2843 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 412 0.45606E+00 0.76539E-03 |
2844 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 412, Nb. of FGMRES iterations = 8 |
2845 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 13 413 0.32157E+00 0.35925E-03 |
2846 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 13 / 413, Nb. of FGMRES iterations = 8 |
2847 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 14 414 0.15754E+00 0.10479E-03 |
2848 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 14 / 414, Nb. of FGMRES iterations = 13 |
2849 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 15 415 0.10000E+00 0.14626E-04 |
2850 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 15 / 415, Nb. of FGMRES iterations = 15 |
2851 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 16 416 0.10000E+00 0.13227E-05 |
2852 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 16 / 416, Nb. of FGMRES iterations = 18 |
2853 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 17 417 0.10000E+00 0.12338E-06 |
2854 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 17 / 417, Nb. of FGMRES iterations = 20 |
2855 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 18 418 0.10000E+00 0.10595E-07 |
2856 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 18 / 418, Nb. of FGMRES iterations = 20 |
2857 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 19 419 0.10000E+00 0.92713E-09 |
2858 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 19 / 419, Nb. of FGMRES iterations = 21 |
2859 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 20 420 0.10000E+00 0.91368E-10 |
2860 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 20 / 420, Nb. of FGMRES iterations = 20 |
2861 |
(PID.TID 0000.0001) // ======================================================= |
2862 |
(PID.TID 0000.0001) // Begin JFNK statistics |
2863 |
(PID.TID 0000.0001) // ======================================================= |
2864 |
(PID.TID 0000.0001) %JFNK_MON: time step = 3 |
2865 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
2866 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 21 |
2867 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 172 |
2868 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
2869 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
2870 |
(PID.TID 0000.0001) // ======================================================= |
2871 |
(PID.TID 0000.0001) // End JFNK statistics |
2872 |
(PID.TID 0000.0001) // ======================================================= |
2873 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 172 in timestep 3 |
2874 |
(PID.TID 0000.0001) // ======================================================= |
2875 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
2876 |
(PID.TID 0000.0001) // ======================================================= |
2877 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 3 |
2878 |
(PID.TID 0000.0001) %MON seaice_time_sec = 5.4000000000000E+03 |
2879 |
(PID.TID 0000.0001) %MON seaice_uice_max = 6.9617980516486E-01 |
2880 |
(PID.TID 0000.0001) %MON seaice_uice_min = 2.8016533581374E-01 |
2881 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3335364276792E-01 |
2882 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 7.9646549378435E-02 |
2883 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 1.0278038393277E-04 |
2884 |
(PID.TID 0000.0001) %MON seaice_vice_max = 1.5445588658480E-01 |
2885 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.2864322475720E-01 |
2886 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -1.4256785932976E-03 |
2887 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.3970954804821E-02 |
2888 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 5.5662090763172E-05 |
2889 |
(PID.TID 0000.0001) // ======================================================= |
2890 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
2891 |
(PID.TID 0000.0001) // ======================================================= |
2892 |
(PID.TID 0000.0001) // ======================================================= |
2893 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
2894 |
(PID.TID 0000.0001) // ======================================================= |
2895 |
(PID.TID 0000.0001) %MON thSI_time_sec = 5.4000000000000E+03 |
2896 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.9305420385756E+10 |
2897 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.9315569980581E+10 |
2898 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9989850405174E+10 |
2899 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0056151340880E-01 |
2900 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0126021681266E-01 |
2901 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0004931122939E-01 |
2902 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 2.7290322031499E-01 |
2903 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0034527036261E-01 |
2904 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
2905 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
2906 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
2907 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
2908 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
2909 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
2910 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
2911 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
2912 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
2913 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
2914 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
2915 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
2916 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
2917 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
2918 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
2919 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
2920 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
2921 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
2922 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
2923 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
2924 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
2925 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
2926 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
2927 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
2928 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
2929 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
2930 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
2931 |
(PID.TID 0000.0001) // ======================================================= |
2932 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
2933 |
(PID.TID 0000.0001) // ======================================================= |
2934 |
Computing Diagnostic # 153 SIuice Counter: 1 Parms: UU M1 |
2935 |
Vector Mate for SIuice Diagnostic # 154 SIvice exists |
2936 |
Computing Diagnostic # 154 SIvice Counter: 1 Parms: VV M1 |
2937 |
Vector Mate for SIvice Diagnostic # 153 SIuice exists |
2938 |
Computing Diagnostic # 147 SIheff Counter: 1 Parms: SM M1 |
2939 |
Computing Diagnostic # 214 SI_Fract Counter: 1 Parms: SM P M1 |
2940 |
Computing Diagnostic # 215 SI_Thick Counter: 1 Parms: SM PC M1 |
2941 |
use Counter Mate for SI_Thick Diagnostic # 214 SI_Fract |
2942 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 601 0.99000E+00 0.93912E-02 |
2943 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 601, Nb. of FGMRES iterations = 1 |
2944 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 602 0.99000E+00 0.55557E-02 |
2945 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 602, Nb. of FGMRES iterations = 1 |
2946 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 603 0.70178E+00 0.43874E-02 |
2947 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 603, Nb. of FGMRES iterations = 2 |
2948 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 604 0.36197E+00 0.22284E-02 |
2949 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 604, Nb. of FGMRES iterations = 4 |
2950 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 605 0.44036E+00 0.12898E-02 |
2951 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 605, Nb. of FGMRES iterations = 2 |
2952 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 606 0.24470E+00 0.50461E-03 |
2953 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 606, Nb. of FGMRES iterations = 8 |
2954 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 607 0.12975E+00 0.12933E-03 |
2955 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 607, Nb. of FGMRES iterations = 11 |
2956 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 608 0.10000E+00 0.15070E-04 |
2957 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 608, Nb. of FGMRES iterations = 11 |
2958 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 609 0.10000E+00 0.13968E-05 |
2959 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 609, Nb. of FGMRES iterations = 19 |
2960 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 610 0.10000E+00 0.12135E-06 |
2961 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 610, Nb. of FGMRES iterations = 20 |
2962 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 611 0.10000E+00 0.11878E-07 |
2963 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 611, Nb. of FGMRES iterations = 21 |
2964 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 612 0.10000E+00 0.10003E-08 |
2965 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 612, Nb. of FGMRES iterations = 21 |
2966 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 13 613 0.10000E+00 0.94049E-10 |
2967 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 13 / 613, Nb. of FGMRES iterations = 21 |
2968 |
(PID.TID 0000.0001) // ======================================================= |
2969 |
(PID.TID 0000.0001) // Begin JFNK statistics |
2970 |
(PID.TID 0000.0001) // ======================================================= |
2971 |
(PID.TID 0000.0001) %JFNK_MON: time step = 4 |
2972 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
2973 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 14 |
2974 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 142 |
2975 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
2976 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
2977 |
(PID.TID 0000.0001) // ======================================================= |
2978 |
(PID.TID 0000.0001) // End JFNK statistics |
2979 |
(PID.TID 0000.0001) // ======================================================= |
2980 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 142 in timestep 4 |
2981 |
(PID.TID 0000.0001) // ======================================================= |
2982 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
2983 |
(PID.TID 0000.0001) // ======================================================= |
2984 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 4 |
2985 |
(PID.TID 0000.0001) %MON seaice_time_sec = 7.2000000000000E+03 |
2986 |
(PID.TID 0000.0001) %MON seaice_uice_max = 6.9777354529113E-01 |
2987 |
(PID.TID 0000.0001) %MON seaice_uice_min = 2.4378900755251E-01 |
2988 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3306497215001E-01 |
2989 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 8.0650992759413E-02 |
2990 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 1.3744620179051E-04 |
2991 |
(PID.TID 0000.0001) %MON seaice_vice_max = 1.6615517344648E-01 |
2992 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.2985971778837E-01 |
2993 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -1.2590577372917E-03 |
2994 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.4704441160023E-02 |
2995 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 6.7571353932506E-05 |
2996 |
(PID.TID 0000.0001) // ======================================================= |
2997 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
2998 |
(PID.TID 0000.0001) // ======================================================= |
2999 |
(PID.TID 0000.0001) // ======================================================= |
3000 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
3001 |
(PID.TID 0000.0001) // ======================================================= |
3002 |
(PID.TID 0000.0001) %MON thSI_time_sec = 7.2000000000000E+03 |
3003 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.9241328624347E+10 |
3004 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.9254712955695E+10 |
3005 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9986615668652E+10 |
3006 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0074715890290E-01 |
3007 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0167920125153E-01 |
3008 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0006526495125E-01 |
3009 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 2.9021308897196E-01 |
3010 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0046801091724E-01 |
3011 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
3012 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
3013 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
3014 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
3015 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
3016 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
3017 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
3018 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
3019 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
3020 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
3021 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
3022 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
3023 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
3024 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
3025 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
3026 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
3027 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
3028 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
3029 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
3030 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
3031 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
3032 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
3033 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
3034 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
3035 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
3036 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
3037 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
3038 |
(PID.TID 0000.0001) // ======================================================= |
3039 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
3040 |
(PID.TID 0000.0001) // ======================================================= |
3041 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 801 0.99000E+00 0.77619E-02 |
3042 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 801, Nb. of FGMRES iterations = 1 |
3043 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 802 0.99000E+00 0.40573E-02 |
3044 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 802, Nb. of FGMRES iterations = 1 |
3045 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 803 0.62981E+00 0.29811E-02 |
3046 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 803, Nb. of FGMRES iterations = 2 |
3047 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 804 0.47792E+00 0.18223E-02 |
3048 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 804, Nb. of FGMRES iterations = 3 |
3049 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 805 0.48381E+00 0.11231E-02 |
3050 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 805, Nb. of FGMRES iterations = 1 |
3051 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 806 0.21761E+00 0.40631E-03 |
3052 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 806, Nb. of FGMRES iterations = 8 |
3053 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 807 0.11759E+00 0.97524E-04 |
3054 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 807, Nb. of FGMRES iterations = 12 |
3055 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 808 0.10000E+00 0.11137E-04 |
3056 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 808, Nb. of FGMRES iterations = 17 |
3057 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 809 0.10000E+00 0.10860E-05 |
3058 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 809, Nb. of FGMRES iterations = 20 |
3059 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 810 0.10000E+00 0.10247E-06 |
3060 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 810, Nb. of FGMRES iterations = 21 |
3061 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 811 0.10000E+00 0.89778E-08 |
3062 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 811, Nb. of FGMRES iterations = 20 |
3063 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 812 0.10000E+00 0.77417E-09 |
3064 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 812, Nb. of FGMRES iterations = 22 |
3065 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 13 813 0.10000E+00 0.72570E-10 |
3066 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 13 / 813, Nb. of FGMRES iterations = 21 |
3067 |
(PID.TID 0000.0001) // ======================================================= |
3068 |
(PID.TID 0000.0001) // Begin JFNK statistics |
3069 |
(PID.TID 0000.0001) // ======================================================= |
3070 |
(PID.TID 0000.0001) %JFNK_MON: time step = 5 |
3071 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
3072 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 14 |
3073 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 149 |
3074 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
3075 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
3076 |
(PID.TID 0000.0001) // ======================================================= |
3077 |
(PID.TID 0000.0001) // End JFNK statistics |
3078 |
(PID.TID 0000.0001) // ======================================================= |
3079 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 149 in timestep 5 |
3080 |
(PID.TID 0000.0001) // ======================================================= |
3081 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
3082 |
(PID.TID 0000.0001) // ======================================================= |
3083 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 5 |
3084 |
(PID.TID 0000.0001) %MON seaice_time_sec = 9.0000000000000E+03 |
3085 |
(PID.TID 0000.0001) %MON seaice_uice_max = 6.9929152662314E-01 |
3086 |
(PID.TID 0000.0001) %MON seaice_uice_min = 2.1612239319136E-01 |
3087 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3276463943228E-01 |
3088 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 8.1569266815069E-02 |
3089 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 1.6490218088899E-04 |
3090 |
(PID.TID 0000.0001) %MON seaice_vice_max = 1.7606317466395E-01 |
3091 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.3070713185558E-01 |
3092 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -1.1138781107263E-03 |
3093 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.5212013101527E-02 |
3094 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 8.2560950071303E-05 |
3095 |
(PID.TID 0000.0001) // ======================================================= |
3096 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
3097 |
(PID.TID 0000.0001) // ======================================================= |
3098 |
(PID.TID 0000.0001) // ======================================================= |
3099 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
3100 |
(PID.TID 0000.0001) // ======================================================= |
3101 |
(PID.TID 0000.0001) %MON thSI_time_sec = 9.0000000000000E+03 |
3102 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.9177575006471E+10 |
3103 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.9194127144391E+10 |
3104 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9983447862080E+10 |
3105 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0093216622149E-01 |
3106 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0209736022284E-01 |
3107 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0008139362327E-01 |
3108 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 3.0542139608814E-01 |
3109 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0068712441900E-01 |
3110 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
3111 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
3112 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
3113 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
3114 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
3115 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
3116 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
3117 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
3118 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
3119 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
3120 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
3121 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
3122 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
3123 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
3124 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
3125 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
3126 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
3127 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
3128 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
3129 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
3130 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
3131 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
3132 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
3133 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
3134 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
3135 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
3136 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
3137 |
(PID.TID 0000.0001) // ======================================================= |
3138 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
3139 |
(PID.TID 0000.0001) // ======================================================= |
3140 |
Compute Stats, Diag. # 214 SI_Fract vol( 0 ): 2.780E+11 Parms: SM P M1 |
3141 |
Compute Stats, Diag. # 215 SI_Thick vol( 0 ): 2.774E+11 Parms: SM PC M1 |
3142 |
use Counter Mate # 214 SI_Fract vol( 0 ): 2.780E+11 integral 2.774E+11 |
3143 |
Compute Stats, Diag. # 144 SIarea vol( 0 ): 2.780E+11 Parms: SM M1 |
3144 |
Compute Stats, Diag. # 147 SIheff vol( 0 ): 2.780E+11 Parms: SM M1 |
3145 |
Compute Stats, Diag. # 153 SIuice vol( 0 ): 2.760E+11 Parms: UU M1 |
3146 |
Compute Stats, Diag. # 154 SIvice vol( 0 ): 2.700E+11 Parms: VV M1 |
3147 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 1001 0.99000E+00 0.64678E-02 |
3148 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 1001, Nb. of FGMRES iterations = 1 |
3149 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 1002 0.34868E+00 0.32041E-02 |
3150 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 1002, Nb. of FGMRES iterations = 4 |
3151 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 1003 0.76158E+00 0.26721E-02 |
3152 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 1003, Nb. of FGMRES iterations = 1 |
3153 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 1004 0.32561E+00 0.12647E-02 |
3154 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 1004, Nb. of FGMRES iterations = 5 |
3155 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 1005 0.17912E+00 0.40187E-03 |
3156 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 1005, Nb. of FGMRES iterations = 8 |
3157 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 1006 0.16277E+00 0.11980E-03 |
3158 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 1006, Nb. of FGMRES iterations = 9 |
3159 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 1007 0.10000E+00 0.14112E-04 |
3160 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 1007, Nb. of FGMRES iterations = 17 |
3161 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 1008 0.10000E+00 0.11313E-05 |
3162 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 1008, Nb. of FGMRES iterations = 20 |
3163 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 1009 0.10000E+00 0.10576E-06 |
3164 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 1009, Nb. of FGMRES iterations = 20 |
3165 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 1010 0.10000E+00 0.87049E-08 |
3166 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 1010, Nb. of FGMRES iterations = 21 |
3167 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 1011 0.10000E+00 0.77798E-09 |
3168 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 1011, Nb. of FGMRES iterations = 21 |
3169 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 1012 0.10000E+00 0.72397E-10 |
3170 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 1012, Nb. of FGMRES iterations = 21 |
3171 |
(PID.TID 0000.0001) // ======================================================= |
3172 |
(PID.TID 0000.0001) // Begin JFNK statistics |
3173 |
(PID.TID 0000.0001) // ======================================================= |
3174 |
(PID.TID 0000.0001) %JFNK_MON: time step = 6 |
3175 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
3176 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 13 |
3177 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 148 |
3178 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
3179 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
3180 |
(PID.TID 0000.0001) // ======================================================= |
3181 |
(PID.TID 0000.0001) // End JFNK statistics |
3182 |
(PID.TID 0000.0001) // ======================================================= |
3183 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 148 in timestep 6 |
3184 |
(PID.TID 0000.0001) // ======================================================= |
3185 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
3186 |
(PID.TID 0000.0001) // ======================================================= |
3187 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 6 |
3188 |
(PID.TID 0000.0001) %MON seaice_time_sec = 1.0800000000000E+04 |
3189 |
(PID.TID 0000.0001) %MON seaice_uice_max = 7.0058372539837E-01 |
3190 |
(PID.TID 0000.0001) %MON seaice_uice_min = 1.9490193978672E-01 |
3191 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3249225617740E-01 |
3192 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 8.2398772124653E-02 |
3193 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 1.8344780992580E-04 |
3194 |
(PID.TID 0000.0001) %MON seaice_vice_max = 1.8412279321075E-01 |
3195 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.3175749375209E-01 |
3196 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -9.8313864020926E-04 |
3197 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.5630628163709E-02 |
3198 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 1.0075385183238E-04 |
3199 |
(PID.TID 0000.0001) // ======================================================= |
3200 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
3201 |
(PID.TID 0000.0001) // ======================================================= |
3202 |
(PID.TID 0000.0001) // ======================================================= |
3203 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
3204 |
(PID.TID 0000.0001) // ======================================================= |
3205 |
(PID.TID 0000.0001) %MON thSI_time_sec = 1.0800000000000E+04 |
3206 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.9114108892854E+10 |
3207 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.9133797136140E+10 |
3208 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9980311756713E+10 |
3209 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0111667823930E-01 |
3210 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0251501878509E-01 |
3211 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0009770244851E-01 |
3212 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 3.1921700488182E-01 |
3213 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0096439775048E-01 |
3214 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
3215 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
3216 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
3217 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
3218 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
3219 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
3220 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
3221 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
3222 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
3223 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
3224 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
3225 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
3226 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
3227 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
3228 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
3229 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
3230 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
3231 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
3232 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
3233 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
3234 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
3235 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
3236 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
3237 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
3238 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
3239 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
3240 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
3241 |
(PID.TID 0000.0001) // ======================================================= |
3242 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
3243 |
(PID.TID 0000.0001) // ======================================================= |
3244 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 1201 0.99000E+00 0.54742E-02 |
3245 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 1201, Nb. of FGMRES iterations = 1 |
3246 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 1202 0.99000E+00 0.28644E-02 |
3247 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 1202, Nb. of FGMRES iterations = 1 |
3248 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 1203 0.60421E+00 0.20472E-02 |
3249 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 1203, Nb. of FGMRES iterations = 2 |
3250 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 1204 0.41714E+00 0.11429E-02 |
3251 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 1204, Nb. of FGMRES iterations = 5 |
3252 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 1205 0.26187E+00 0.46781E-03 |
3253 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 1205, Nb. of FGMRES iterations = 6 |
3254 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 1206 0.17468E+00 0.14618E-03 |
3255 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 1206, Nb. of FGMRES iterations = 12 |
3256 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 1207 0.10000E+00 0.24494E-04 |
3257 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 1207, Nb. of FGMRES iterations = 18 |
3258 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 1208 0.10000E+00 0.19893E-05 |
3259 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 1208, Nb. of FGMRES iterations = 18 |
3260 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 1209 0.10000E+00 0.16944E-06 |
3261 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 1209, Nb. of FGMRES iterations = 19 |
3262 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 1210 0.10000E+00 0.14940E-07 |
3263 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 1210, Nb. of FGMRES iterations = 19 |
3264 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 1211 0.10000E+00 0.13964E-08 |
3265 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 1211, Nb. of FGMRES iterations = 20 |
3266 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 1212 0.10000E+00 0.11694E-09 |
3267 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 1212, Nb. of FGMRES iterations = 20 |
3268 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 13 1213 0.10000E+00 0.10678E-10 |
3269 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 13 / 1213, Nb. of FGMRES iterations = 20 |
3270 |
(PID.TID 0000.0001) // ======================================================= |
3271 |
(PID.TID 0000.0001) // Begin JFNK statistics |
3272 |
(PID.TID 0000.0001) // ======================================================= |
3273 |
(PID.TID 0000.0001) %JFNK_MON: time step = 7 |
3274 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
3275 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 14 |
3276 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 161 |
3277 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
3278 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
3279 |
(PID.TID 0000.0001) // ======================================================= |
3280 |
(PID.TID 0000.0001) // End JFNK statistics |
3281 |
(PID.TID 0000.0001) // ======================================================= |
3282 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 161 in timestep 7 |
3283 |
(PID.TID 0000.0001) // ======================================================= |
3284 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
3285 |
(PID.TID 0000.0001) // ======================================================= |
3286 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 7 |
3287 |
(PID.TID 0000.0001) %MON seaice_time_sec = 1.2600000000000E+04 |
3288 |
(PID.TID 0000.0001) %MON seaice_uice_max = 7.0168988160357E-01 |
3289 |
(PID.TID 0000.0001) %MON seaice_uice_min = 1.7750371275359E-01 |
3290 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3223317177437E-01 |
3291 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 8.3185450665174E-02 |
3292 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 1.9805848968503E-04 |
3293 |
(PID.TID 0000.0001) %MON seaice_vice_max = 1.9076480282513E-01 |
3294 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.3514402125081E-01 |
3295 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -8.5979763855135E-04 |
3296 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.5999998073457E-02 |
3297 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 1.2228719938699E-04 |
3298 |
(PID.TID 0000.0001) // ======================================================= |
3299 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
3300 |
(PID.TID 0000.0001) // ======================================================= |
3301 |
(PID.TID 0000.0001) // ======================================================= |
3302 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
3303 |
(PID.TID 0000.0001) // ======================================================= |
3304 |
(PID.TID 0000.0001) %MON thSI_time_sec = 1.2600000000000E+04 |
3305 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.9050906290978E+10 |
3306 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.9073712937906E+10 |
3307 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9977193353072E+10 |
3308 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0130076123007E-01 |
3309 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0293236281934E-01 |
3310 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0011416676816E-01 |
3311 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 3.3195093810883E-01 |
3312 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0127944314755E-01 |
3313 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
3314 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
3315 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
3316 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
3317 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
3318 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
3319 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
3320 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
3321 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
3322 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
3323 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
3324 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
3325 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
3326 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
3327 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
3328 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
3329 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
3330 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
3331 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
3332 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
3333 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
3334 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
3335 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
3336 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
3337 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
3338 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
3339 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
3340 |
(PID.TID 0000.0001) // ======================================================= |
3341 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
3342 |
(PID.TID 0000.0001) // ======================================================= |
3343 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 1401 0.99000E+00 0.44908E-02 |
3344 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 1401, Nb. of FGMRES iterations = 1 |
3345 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 1402 0.99000E+00 0.24230E-02 |
3346 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 1402, Nb. of FGMRES iterations = 1 |
3347 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 1403 0.58627E+00 0.16973E-02 |
3348 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 1403, Nb. of FGMRES iterations = 2 |
3349 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 1404 0.42368E+00 0.95746E-03 |
3350 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 1404, Nb. of FGMRES iterations = 6 |
3351 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 1405 0.25612E+00 0.38614E-03 |
3352 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 1405, Nb. of FGMRES iterations = 6 |
3353 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 1406 0.13543E+00 0.10183E-03 |
3354 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 1406, Nb. of FGMRES iterations = 16 |
3355 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 1407 0.10000E+00 0.11287E-04 |
3356 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 1407, Nb. of FGMRES iterations = 18 |
3357 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 1408 0.10000E+00 0.10065E-05 |
3358 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 1408, Nb. of FGMRES iterations = 18 |
3359 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 1409 0.10000E+00 0.97122E-07 |
3360 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 1409, Nb. of FGMRES iterations = 19 |
3361 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 1410 0.10000E+00 0.83526E-08 |
3362 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 1410, Nb. of FGMRES iterations = 19 |
3363 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 1411 0.10000E+00 0.73050E-09 |
3364 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 1411, Nb. of FGMRES iterations = 20 |
3365 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 1412 0.10000E+00 0.67593E-10 |
3366 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 1412, Nb. of FGMRES iterations = 20 |
3367 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 13 1413 0.10000E+00 0.65242E-11 |
3368 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 13 / 1413, Nb. of FGMRES iterations = 20 |
3369 |
(PID.TID 0000.0001) // ======================================================= |
3370 |
(PID.TID 0000.0001) // Begin JFNK statistics |
3371 |
(PID.TID 0000.0001) // ======================================================= |
3372 |
(PID.TID 0000.0001) %JFNK_MON: time step = 8 |
3373 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
3374 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 14 |
3375 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 166 |
3376 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
3377 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
3378 |
(PID.TID 0000.0001) // ======================================================= |
3379 |
(PID.TID 0000.0001) // End JFNK statistics |
3380 |
(PID.TID 0000.0001) // ======================================================= |
3381 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 166 in timestep 8 |
3382 |
(PID.TID 0000.0001) // ======================================================= |
3383 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
3384 |
(PID.TID 0000.0001) // ======================================================= |
3385 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 8 |
3386 |
(PID.TID 0000.0001) %MON seaice_time_sec = 1.4400000000000E+04 |
3387 |
(PID.TID 0000.0001) %MON seaice_uice_max = 7.0265281997604E-01 |
3388 |
(PID.TID 0000.0001) %MON seaice_uice_min = 1.6339454128145E-01 |
3389 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3199106983368E-01 |
3390 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 8.3915965515493E-02 |
3391 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 2.0753569910450E-04 |
3392 |
(PID.TID 0000.0001) %MON seaice_vice_max = 1.9648170297223E-01 |
3393 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.4089172597925E-01 |
3394 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -7.4737925183621E-04 |
3395 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.6344755011088E-02 |
3396 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 1.4068255024083E-04 |
3397 |
(PID.TID 0000.0001) // ======================================================= |
3398 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
3399 |
(PID.TID 0000.0001) // ======================================================= |
3400 |
(PID.TID 0000.0001) // ======================================================= |
3401 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
3402 |
(PID.TID 0000.0001) // ======================================================= |
3403 |
(PID.TID 0000.0001) %MON thSI_time_sec = 1.4400000000000E+04 |
3404 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.8987928050364E+10 |
3405 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.9013837001217E+10 |
3406 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9974091049148E+10 |
3407 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0148452624715E-01 |
3408 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0334961328462E-01 |
3409 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0013081613447E-01 |
3410 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 3.4380632567362E-01 |
3411 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0162864217865E-01 |
3412 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
3413 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
3414 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
3415 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
3416 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
3417 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
3418 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
3419 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
3420 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
3421 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
3422 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
3423 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
3424 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
3425 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
3426 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
3427 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
3428 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
3429 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
3430 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
3431 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
3432 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
3433 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
3434 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
3435 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
3436 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
3437 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
3438 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
3439 |
(PID.TID 0000.0001) // ======================================================= |
3440 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
3441 |
(PID.TID 0000.0001) // ======================================================= |
3442 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 1601 0.99000E+00 0.37151E-02 |
3443 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 1601, Nb. of FGMRES iterations = 1 |
3444 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 1602 0.99000E+00 0.22139E-02 |
3445 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 1602, Nb. of FGMRES iterations = 1 |
3446 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 1603 0.55456E+00 0.14943E-02 |
3447 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 1603, Nb. of FGMRES iterations = 2 |
3448 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 1604 0.40548E+00 0.81864E-03 |
3449 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 1604, Nb. of FGMRES iterations = 7 |
3450 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 1605 0.22661E+00 0.30429E-03 |
3451 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 1605, Nb. of FGMRES iterations = 9 |
3452 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 1606 0.12065E+00 0.74295E-04 |
3453 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 1606, Nb. of FGMRES iterations = 16 |
3454 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 1607 0.10000E+00 0.62573E-05 |
3455 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 1607, Nb. of FGMRES iterations = 16 |
3456 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 1608 0.10000E+00 0.59487E-06 |
3457 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 1608, Nb. of FGMRES iterations = 18 |
3458 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 1609 0.10000E+00 0.56007E-07 |
3459 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 1609, Nb. of FGMRES iterations = 21 |
3460 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 1610 0.10000E+00 0.53737E-08 |
3461 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 1610, Nb. of FGMRES iterations = 21 |
3462 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 1611 0.10000E+00 0.45608E-09 |
3463 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 1611, Nb. of FGMRES iterations = 22 |
3464 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 1612 0.10000E+00 0.42590E-10 |
3465 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 1612, Nb. of FGMRES iterations = 20 |
3466 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 13 1613 0.10000E+00 0.43386E-11 |
3467 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 13 / 1613, Nb. of FGMRES iterations = 22 |
3468 |
(PID.TID 0000.0001) // ======================================================= |
3469 |
(PID.TID 0000.0001) // Begin JFNK statistics |
3470 |
(PID.TID 0000.0001) // ======================================================= |
3471 |
(PID.TID 0000.0001) %JFNK_MON: time step = 9 |
3472 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
3473 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 14 |
3474 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 176 |
3475 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
3476 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
3477 |
(PID.TID 0000.0001) // ======================================================= |
3478 |
(PID.TID 0000.0001) // End JFNK statistics |
3479 |
(PID.TID 0000.0001) // ======================================================= |
3480 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 176 in timestep 9 |
3481 |
(PID.TID 0000.0001) // ======================================================= |
3482 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
3483 |
(PID.TID 0000.0001) // ======================================================= |
3484 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 9 |
3485 |
(PID.TID 0000.0001) %MON seaice_time_sec = 1.6200000000000E+04 |
3486 |
(PID.TID 0000.0001) %MON seaice_uice_max = 7.0353897084108E-01 |
3487 |
(PID.TID 0000.0001) %MON seaice_uice_min = 1.5141077709911E-01 |
3488 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3176458297070E-01 |
3489 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 8.4594070390141E-02 |
3490 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 2.1234510280045E-04 |
3491 |
(PID.TID 0000.0001) %MON seaice_vice_max = 2.0132104546831E-01 |
3492 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.4559283031495E-01 |
3493 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -6.4987452250003E-04 |
3494 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.6665203725128E-02 |
3495 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 1.5127692936952E-04 |
3496 |
(PID.TID 0000.0001) // ======================================================= |
3497 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
3498 |
(PID.TID 0000.0001) // ======================================================= |
3499 |
(PID.TID 0000.0001) // ======================================================= |
3500 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
3501 |
(PID.TID 0000.0001) // ======================================================= |
3502 |
(PID.TID 0000.0001) %MON thSI_time_sec = 1.6200000000000E+04 |
3503 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.8925146045770E+10 |
3504 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.8954147160136E+10 |
3505 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9970998885634E+10 |
3506 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0166805291598E-01 |
3507 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0376688513396E-01 |
3508 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0014770319749E-01 |
3509 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 3.5495566667690E-01 |
3510 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0201049288908E-01 |
3511 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
3512 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
3513 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
3514 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
3515 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
3516 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
3517 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
3518 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
3519 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
3520 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
3521 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
3522 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
3523 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
3524 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
3525 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
3526 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
3527 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
3528 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
3529 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
3530 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
3531 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
3532 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
3533 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
3534 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
3535 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
3536 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
3537 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
3538 |
(PID.TID 0000.0001) // ======================================================= |
3539 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
3540 |
(PID.TID 0000.0001) // ======================================================= |
3541 |
Compute Stats, Diag. # 214 SI_Fract vol( 0 ): 2.780E+11 Parms: SM P M1 |
3542 |
Compute Stats, Diag. # 215 SI_Thick vol( 0 ): 2.763E+11 Parms: SM PC M1 |
3543 |
use Counter Mate # 214 SI_Fract vol( 0 ): 2.780E+11 integral 2.763E+11 |
3544 |
Compute Stats, Diag. # 144 SIarea vol( 0 ): 2.780E+11 Parms: SM M1 |
3545 |
Compute Stats, Diag. # 147 SIheff vol( 0 ): 2.780E+11 Parms: SM M1 |
3546 |
Compute Stats, Diag. # 153 SIuice vol( 0 ): 2.760E+11 Parms: UU M1 |
3547 |
Compute Stats, Diag. # 154 SIvice vol( 0 ): 2.700E+11 Parms: VV M1 |
3548 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 1801 0.99000E+00 0.36251E-02 |
3549 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 1801, Nb. of FGMRES iterations = 1 |
3550 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 1802 0.99000E+00 0.21474E-02 |
3551 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 1802, Nb. of FGMRES iterations = 1 |
3552 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 1803 0.53915E+00 0.14225E-02 |
3553 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 1803, Nb. of FGMRES iterations = 2 |
3554 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 1804 0.39366E+00 0.76406E-03 |
3555 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 1804, Nb. of FGMRES iterations = 7 |
3556 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 1805 0.22628E+00 0.28372E-03 |
3557 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 1805, Nb. of FGMRES iterations = 10 |
3558 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 1806 0.11512E+00 0.67140E-04 |
3559 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 1806, Nb. of FGMRES iterations = 14 |
3560 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 1807 0.10000E+00 0.65165E-05 |
3561 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 1807, Nb. of FGMRES iterations = 17 |
3562 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 1808 0.10000E+00 0.50634E-06 |
3563 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 1808, Nb. of FGMRES iterations = 20 |
3564 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 1809 0.10000E+00 0.48550E-07 |
3565 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 1809, Nb. of FGMRES iterations = 21 |
3566 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 1810 0.10000E+00 0.42139E-08 |
3567 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 1810, Nb. of FGMRES iterations = 21 |
3568 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 1811 0.10000E+00 0.37830E-09 |
3569 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 1811, Nb. of FGMRES iterations = 23 |
3570 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 1812 0.10000E+00 0.30997E-10 |
3571 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 1812, Nb. of FGMRES iterations = 22 |
3572 |
(PID.TID 0000.0001) // ======================================================= |
3573 |
(PID.TID 0000.0001) // Begin JFNK statistics |
3574 |
(PID.TID 0000.0001) // ======================================================= |
3575 |
(PID.TID 0000.0001) %JFNK_MON: time step = 10 |
3576 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
3577 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 13 |
3578 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 159 |
3579 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
3580 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
3581 |
(PID.TID 0000.0001) // ======================================================= |
3582 |
(PID.TID 0000.0001) // End JFNK statistics |
3583 |
(PID.TID 0000.0001) // ======================================================= |
3584 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 159 in timestep 10 |
3585 |
(PID.TID 0000.0001) // ======================================================= |
3586 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
3587 |
(PID.TID 0000.0001) // ======================================================= |
3588 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 10 |
3589 |
(PID.TID 0000.0001) %MON seaice_time_sec = 1.8000000000000E+04 |
3590 |
(PID.TID 0000.0001) %MON seaice_uice_max = 7.0439128075802E-01 |
3591 |
(PID.TID 0000.0001) %MON seaice_uice_min = 1.4094325324241E-01 |
3592 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3154980496789E-01 |
3593 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 8.5234325107405E-02 |
3594 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 2.1448492481356E-04 |
3595 |
(PID.TID 0000.0001) %MON seaice_vice_max = 2.0545421644867E-01 |
3596 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.4917117554193E-01 |
3597 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -5.6665647479530E-04 |
3598 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.6966394891098E-02 |
3599 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 1.5615399364563E-04 |
3600 |
(PID.TID 0000.0001) // ======================================================= |
3601 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
3602 |
(PID.TID 0000.0001) // ======================================================= |
3603 |
(PID.TID 0000.0001) // ======================================================= |
3604 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
3605 |
(PID.TID 0000.0001) // ======================================================= |
3606 |
(PID.TID 0000.0001) %MON thSI_time_sec = 1.8000000000000E+04 |
3607 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.8862545648387E+10 |
3608 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.8894633453273E+10 |
3609 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9967912195114E+10 |
3610 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0185138189595E-01 |
3611 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0418426635685E-01 |
3612 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0016483291993E-01 |
3613 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 3.6553682748626E-01 |
3614 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0242123649003E-01 |
3615 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
3616 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
3617 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
3618 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
3619 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
3620 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
3621 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
3622 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
3623 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
3624 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
3625 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
3626 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
3627 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
3628 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
3629 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
3630 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
3631 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
3632 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
3633 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
3634 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
3635 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
3636 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
3637 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
3638 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
3639 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
3640 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
3641 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
3642 |
(PID.TID 0000.0001) // ======================================================= |
3643 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
3644 |
(PID.TID 0000.0001) // ======================================================= |
3645 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 2001 0.99000E+00 0.38027E-02 |
3646 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 2001, Nb. of FGMRES iterations = 1 |
3647 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 2002 0.99000E+00 0.20825E-02 |
3648 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 2002, Nb. of FGMRES iterations = 1 |
3649 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 2003 0.53968E+00 0.13804E-02 |
3650 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 2003, Nb. of FGMRES iterations = 2 |
3651 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 2004 0.41111E+00 0.76320E-03 |
3652 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 2004, Nb. of FGMRES iterations = 5 |
3653 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 2005 0.25804E+00 0.30934E-03 |
3654 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 2005, Nb. of FGMRES iterations = 8 |
3655 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 2006 0.12747E+00 0.78350E-04 |
3656 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 2006, Nb. of FGMRES iterations = 15 |
3657 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 2007 0.10000E+00 0.78226E-05 |
3658 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 2007, Nb. of FGMRES iterations = 18 |
3659 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 2008 0.10000E+00 0.61744E-06 |
3660 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 2008, Nb. of FGMRES iterations = 20 |
3661 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 2009 0.10000E+00 0.55849E-07 |
3662 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 2009, Nb. of FGMRES iterations = 21 |
3663 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 2010 0.10000E+00 0.51399E-08 |
3664 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 2010, Nb. of FGMRES iterations = 21 |
3665 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 2011 0.10000E+00 0.46796E-09 |
3666 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 2011, Nb. of FGMRES iterations = 22 |
3667 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 2012 0.10000E+00 0.46080E-10 |
3668 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 2012, Nb. of FGMRES iterations = 23 |
3669 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 13 2013 0.10000E+00 0.39617E-11 |
3670 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 13 / 2013, Nb. of FGMRES iterations = 22 |
3671 |
(PID.TID 0000.0001) // ======================================================= |
3672 |
(PID.TID 0000.0001) // Begin JFNK statistics |
3673 |
(PID.TID 0000.0001) // ======================================================= |
3674 |
(PID.TID 0000.0001) %JFNK_MON: time step = 11 |
3675 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
3676 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 14 |
3677 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 179 |
3678 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
3679 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
3680 |
(PID.TID 0000.0001) // ======================================================= |
3681 |
(PID.TID 0000.0001) // End JFNK statistics |
3682 |
(PID.TID 0000.0001) // ======================================================= |
3683 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 179 in timestep 11 |
3684 |
(PID.TID 0000.0001) // ======================================================= |
3685 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
3686 |
(PID.TID 0000.0001) // ======================================================= |
3687 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 11 |
3688 |
(PID.TID 0000.0001) %MON seaice_time_sec = 1.9800000000000E+04 |
3689 |
(PID.TID 0000.0001) %MON seaice_uice_max = 7.0521874835368E-01 |
3690 |
(PID.TID 0000.0001) %MON seaice_uice_min = 1.3169456055619E-01 |
3691 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3134430290149E-01 |
3692 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 8.5845342435786E-02 |
3693 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 2.1582373956439E-04 |
3694 |
(PID.TID 0000.0001) %MON seaice_vice_max = 2.0901517975690E-01 |
3695 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.5183175287808E-01 |
3696 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -4.9507898549471E-04 |
3697 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.7254536214963E-02 |
3698 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 1.5832171783815E-04 |
3699 |
(PID.TID 0000.0001) // ======================================================= |
3700 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
3701 |
(PID.TID 0000.0001) // ======================================================= |
3702 |
(PID.TID 0000.0001) // ======================================================= |
3703 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
3704 |
(PID.TID 0000.0001) // ======================================================= |
3705 |
(PID.TID 0000.0001) %MON thSI_time_sec = 1.9800000000000E+04 |
3706 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.8800116157597E+10 |
3707 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.8835291024111E+10 |
3708 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9964825133486E+10 |
3709 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0203454261850E-01 |
3710 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0460183309000E-01 |
3711 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0018219952325E-01 |
3712 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 3.7563976479984E-01 |
3713 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0286004850043E-01 |
3714 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
3715 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
3716 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
3717 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
3718 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
3719 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
3720 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
3721 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
3722 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
3723 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
3724 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
3725 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
3726 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
3727 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
3728 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
3729 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
3730 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
3731 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
3732 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
3733 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
3734 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
3735 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
3736 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
3737 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
3738 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
3739 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
3740 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
3741 |
(PID.TID 0000.0001) // ======================================================= |
3742 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
3743 |
(PID.TID 0000.0001) // ======================================================= |
3744 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 1 2201 0.99000E+00 0.38843E-02 |
3745 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 1 / 2201, Nb. of FGMRES iterations = 1 |
3746 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 2 2202 0.99000E+00 0.20377E-02 |
3747 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 2 / 2202, Nb. of FGMRES iterations = 1 |
3748 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 3 2203 0.52289E+00 0.13226E-02 |
3749 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 3 / 2203, Nb. of FGMRES iterations = 3 |
3750 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 4 2204 0.34308E+00 0.64816E-03 |
3751 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 4 / 2204, Nb. of FGMRES iterations = 5 |
3752 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 5 2205 0.22387E+00 0.23898E-03 |
3753 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 5 / 2205, Nb. of FGMRES iterations = 13 |
3754 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 6 2206 0.10000E+00 0.45793E-04 |
3755 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 6 / 2206, Nb. of FGMRES iterations = 16 |
3756 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 7 2207 0.10000E+00 0.33553E-05 |
3757 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 7 / 2207, Nb. of FGMRES iterations = 17 |
3758 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 8 2208 0.10000E+00 0.27029E-06 |
3759 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 8 / 2208, Nb. of FGMRES iterations = 20 |
3760 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 9 2209 0.10000E+00 0.25532E-07 |
3761 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 9 / 2209, Nb. of FGMRES iterations = 22 |
3762 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 10 2210 0.10000E+00 0.23577E-08 |
3763 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 10 / 2210, Nb. of FGMRES iterations = 22 |
3764 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 11 2211 0.10000E+00 0.23040E-09 |
3765 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 11 / 2211, Nb. of FGMRES iterations = 23 |
3766 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm = 12 2212 0.10000E+00 0.18652E-10 |
3767 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Newton iterate / total = 12 / 2212, Nb. of FGMRES iterations = 22 |
3768 |
(PID.TID 0000.0001) // ======================================================= |
3769 |
(PID.TID 0000.0001) // Begin JFNK statistics |
3770 |
(PID.TID 0000.0001) // ======================================================= |
3771 |
(PID.TID 0000.0001) %JFNK_MON: time step = 12 |
3772 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of time steps = 1 |
3773 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton steps = 13 |
3774 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov steps = 165 |
3775 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Newton failures = 0 |
3776 |
(PID.TID 0000.0001) %JFNK_MON: Nb. of Krylov failures = 0 |
3777 |
(PID.TID 0000.0001) // ======================================================= |
3778 |
(PID.TID 0000.0001) // End JFNK statistics |
3779 |
(PID.TID 0000.0001) // ======================================================= |
3780 |
(PID.TID 0000.0001) S/R SEAICE_JFNK: Total number FGMRES iterations = 165 in timestep 12 |
3781 |
(PID.TID 0000.0001) // ======================================================= |
3782 |
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics |
3783 |
(PID.TID 0000.0001) // ======================================================= |
3784 |
(PID.TID 0000.0001) %MON seaice_tsnumber = 12 |
3785 |
(PID.TID 0000.0001) %MON seaice_time_sec = 2.1600000000000E+04 |
3786 |
(PID.TID 0000.0001) %MON seaice_uice_max = 7.0602148913497E-01 |
3787 |
(PID.TID 0000.0001) %MON seaice_uice_min = 1.2347910931460E-01 |
3788 |
(PID.TID 0000.0001) %MON seaice_uice_mean = 5.3114668036109E-01 |
3789 |
(PID.TID 0000.0001) %MON seaice_uice_sd = 8.6431976663978E-02 |
3790 |
(PID.TID 0000.0001) %MON seaice_uice_del2 = 2.1838191506481E-04 |
3791 |
(PID.TID 0000.0001) %MON seaice_vice_max = 2.1209429325138E-01 |
3792 |
(PID.TID 0000.0001) %MON seaice_vice_min = -1.5375140279628E-01 |
3793 |
(PID.TID 0000.0001) %MON seaice_vice_mean = -4.3160097843498E-04 |
3794 |
(PID.TID 0000.0001) %MON seaice_vice_sd = 5.7532926017494E-02 |
3795 |
(PID.TID 0000.0001) %MON seaice_vice_del2 = 1.5885329062977E-04 |
3796 |
(PID.TID 0000.0001) // ======================================================= |
3797 |
(PID.TID 0000.0001) // End MONITOR SEAICE statistics |
3798 |
(PID.TID 0000.0001) // ======================================================= |
3799 |
(PID.TID 0000.0001) // ======================================================= |
3800 |
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics |
3801 |
(PID.TID 0000.0001) // ======================================================= |
3802 |
(PID.TID 0000.0001) %MON thSI_time_sec = 2.1600000000000E+04 |
3803 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_G = 6.8737842136367E+10 |
3804 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_S = 2.8776110435516E+10 |
3805 |
(PID.TID 0000.0001) %MON thSI_Ice_Area_N = 3.9961731700851E+10 |
3806 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_G = 2.0221757867266E-01 |
3807 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_S = 2.0501969013795E-01 |
3808 |
(PID.TID 0000.0001) %MON thSI_IceH_ave_N = 2.0019980152573E-01 |
3809 |
(PID.TID 0000.0001) %MON thSI_IceH_max_S = 3.8532602367638E-01 |
3810 |
(PID.TID 0000.0001) %MON thSI_IceH_max_N = 2.0332415570897E-01 |
3811 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G = 0.0000000000000E+00 |
3812 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S = 0.0000000000000E+00 |
3813 |
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N = 0.0000000000000E+00 |
3814 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_S = 0.0000000000000E+00 |
3815 |
(PID.TID 0000.0001) %MON thSI_SnwH_max_N = 0.0000000000000E+00 |
3816 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G = 0.0000000000000E+00 |
3817 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S = 0.0000000000000E+00 |
3818 |
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N = 0.0000000000000E+00 |
3819 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S = 0.0000000000000E+00 |
3820 |
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N = 0.0000000000000E+00 |
3821 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S = 0.0000000000000E+00 |
3822 |
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N = 0.0000000000000E+00 |
3823 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G = 0.0000000000000E+00 |
3824 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S = 0.0000000000000E+00 |
3825 |
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N = 0.0000000000000E+00 |
3826 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_S = 0.0000000000000E+00 |
3827 |
(PID.TID 0000.0001) %MON thSI_Tic1_min_N = 0.0000000000000E+00 |
3828 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_S = 0.0000000000000E+00 |
3829 |
(PID.TID 0000.0001) %MON thSI_Tic1_max_N = 0.0000000000000E+00 |
3830 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G = 0.0000000000000E+00 |
3831 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S = 0.0000000000000E+00 |
3832 |
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N = 0.0000000000000E+00 |
3833 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_S = 0.0000000000000E+00 |
3834 |
(PID.TID 0000.0001) %MON thSI_Tic2_min_N = 0.0000000000000E+00 |
3835 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_S = 0.0000000000000E+00 |
3836 |
(PID.TID 0000.0001) %MON thSI_Tic2_max_N = 0.0000000000000E+00 |
3837 |
(PID.TID 0000.0001) %MON thSI_TotEnerg_G = -4.1574014390118E+18 |
3838 |
(PID.TID 0000.0001) // ======================================================= |
3839 |
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics |
3840 |
(PID.TID 0000.0001) // ======================================================= |
3841 |
Compute Stats, Diag. # 214 SI_Fract vol( 0 ): 2.085E+11 Parms: SM P M1 |
3842 |
Compute Stats, Diag. # 215 SI_Thick vol( 0 ): 2.066E+11 Parms: SM PC M1 |
3843 |
use Counter Mate # 214 SI_Fract vol( 0 ): 2.085E+11 integral 2.066E+11 |
3844 |
Compute Stats, Diag. # 144 SIarea vol( 0 ): 2.085E+11 Parms: SM M1 |
3845 |
Compute Stats, Diag. # 147 SIheff vol( 0 ): 2.085E+11 Parms: SM M1 |
3846 |
Compute Stats, Diag. # 153 SIuice vol( 0 ): 2.070E+11 Parms: UU M1 |
3847 |
Compute Stats, Diag. # 154 SIvice vol( 0 ): 2.025E+11 Parms: VV M1 |
3848 |
(PID.TID 0000.0001) DIAGSTATS_CLOSE_IO: close file: iceStDiag.0000000000.txt , unit= 9 |
3849 |
(PID.TID 0000.0001) %CHECKPOINT 12 ckptA |
3850 |
(PID.TID 0000.0001) Seconds in section "ALL [THE_MODEL_MAIN]": |
3851 |
(PID.TID 0000.0001) User time: 180.89000000000001 |
3852 |
(PID.TID 0000.0001) System time: 0.20000000000000001 |
3853 |
(PID.TID 0000.0001) Wall clock time: 181.13725304603577 |
3854 |
(PID.TID 0000.0001) No. starts: 1 |
3855 |
(PID.TID 0000.0001) No. stops: 1 |
3856 |
(PID.TID 0000.0001) Seconds in section "INITIALISE_FIXED [THE_MODEL_MAIN]": |
3857 |
(PID.TID 0000.0001) User time: 4.0000000000000001E-002 |
3858 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3859 |
(PID.TID 0000.0001) Wall clock time: 4.6086788177490234E-002 |
3860 |
(PID.TID 0000.0001) No. starts: 1 |
3861 |
(PID.TID 0000.0001) No. stops: 1 |
3862 |
(PID.TID 0000.0001) Seconds in section "THE_MAIN_LOOP [THE_MODEL_MAIN]": |
3863 |
(PID.TID 0000.0001) User time: 180.85000000000002 |
3864 |
(PID.TID 0000.0001) System time: 0.20000000000000001 |
3865 |
(PID.TID 0000.0001) Wall clock time: 181.09112501144409 |
3866 |
(PID.TID 0000.0001) No. starts: 1 |
3867 |
(PID.TID 0000.0001) No. stops: 1 |
3868 |
(PID.TID 0000.0001) Seconds in section "INITIALISE_VARIA [THE_MAIN_LOOP]": |
3869 |
(PID.TID 0000.0001) User time: 4.0000000000000001E-002 |
3870 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3871 |
(PID.TID 0000.0001) Wall clock time: 3.8655996322631836E-002 |
3872 |
(PID.TID 0000.0001) No. starts: 1 |
3873 |
(PID.TID 0000.0001) No. stops: 1 |
3874 |
(PID.TID 0000.0001) Seconds in section "MAIN LOOP [THE_MAIN_LOOP]": |
3875 |
(PID.TID 0000.0001) User time: 180.81000000000000 |
3876 |
(PID.TID 0000.0001) System time: 0.20000000000000001 |
3877 |
(PID.TID 0000.0001) Wall clock time: 181.05244493484497 |
3878 |
(PID.TID 0000.0001) No. starts: 1 |
3879 |
(PID.TID 0000.0001) No. stops: 1 |
3880 |
(PID.TID 0000.0001) Seconds in section "MAIN_DO_LOOP [THE_MAIN_LOOP]": |
3881 |
(PID.TID 0000.0001) User time: 180.81000000000012 |
3882 |
(PID.TID 0000.0001) System time: 0.20000000000000001 |
3883 |
(PID.TID 0000.0001) Wall clock time: 181.05235195159912 |
3884 |
(PID.TID 0000.0001) No. starts: 12 |
3885 |
(PID.TID 0000.0001) No. stops: 12 |
3886 |
(PID.TID 0000.0001) Seconds in section "FORWARD_STEP [MAIN_DO_LOOP]": |
3887 |
(PID.TID 0000.0001) User time: 180.81000000000012 |
3888 |
(PID.TID 0000.0001) System time: 0.20000000000000001 |
3889 |
(PID.TID 0000.0001) Wall clock time: 181.05216956138611 |
3890 |
(PID.TID 0000.0001) No. starts: 12 |
3891 |
(PID.TID 0000.0001) No. stops: 12 |
3892 |
(PID.TID 0000.0001) Seconds in section "DO_STATEVARS_DIAGS [FORWARD_STEP]": |
3893 |
(PID.TID 0000.0001) User time: 2.0000000000010232E-002 |
3894 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3895 |
(PID.TID 0000.0001) Wall clock time: 2.7935504913330078E-002 |
3896 |
(PID.TID 0000.0001) No. starts: 36 |
3897 |
(PID.TID 0000.0001) No. stops: 36 |
3898 |
(PID.TID 0000.0001) Seconds in section "LOAD_FIELDS_DRIVER [FORWARD_STEP]": |
3899 |
(PID.TID 0000.0001) User time: 0.10000000000002274 |
3900 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3901 |
(PID.TID 0000.0001) Wall clock time: 8.9586496353149414E-002 |
3902 |
(PID.TID 0000.0001) No. starts: 12 |
3903 |
(PID.TID 0000.0001) No. stops: 12 |
3904 |
(PID.TID 0000.0001) Seconds in section "EXF_GETFORCING [LOAD_FLDS_DRIVER]": |
3905 |
(PID.TID 0000.0001) User time: 0.10000000000002274 |
3906 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3907 |
(PID.TID 0000.0001) Wall clock time: 8.9217662811279297E-002 |
3908 |
(PID.TID 0000.0001) No. starts: 12 |
3909 |
(PID.TID 0000.0001) No. stops: 12 |
3910 |
(PID.TID 0000.0001) Seconds in section "EXTERNAL_FLDS_LOAD [LOAD_FLDS_DRIVER]": |
3911 |
(PID.TID 0000.0001) User time: 0.0000000000000000 |
3912 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3913 |
(PID.TID 0000.0001) Wall clock time: 9.5129013061523438E-005 |
3914 |
(PID.TID 0000.0001) No. starts: 12 |
3915 |
(PID.TID 0000.0001) No. stops: 12 |
3916 |
(PID.TID 0000.0001) Seconds in section "DO_ATMOSPHERIC_PHYS [FORWARD_STEP]": |
3917 |
(PID.TID 0000.0001) User time: 0.0000000000000000 |
3918 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3919 |
(PID.TID 0000.0001) Wall clock time: 8.8214874267578125E-005 |
3920 |
(PID.TID 0000.0001) No. starts: 12 |
3921 |
(PID.TID 0000.0001) No. stops: 12 |
3922 |
(PID.TID 0000.0001) Seconds in section "DO_OCEANIC_PHYS [FORWARD_STEP]": |
3923 |
(PID.TID 0000.0001) User time: 180.58000000000001 |
3924 |
(PID.TID 0000.0001) System time: 0.20000000000000001 |
3925 |
(PID.TID 0000.0001) Wall clock time: 180.83468794822693 |
3926 |
(PID.TID 0000.0001) No. starts: 12 |
3927 |
(PID.TID 0000.0001) No. stops: 12 |
3928 |
(PID.TID 0000.0001) Seconds in section "THSICE_MAIN [DO_OCEANIC_PHYS]": |
3929 |
(PID.TID 0000.0001) User time: 2.0000000000010232E-002 |
3930 |
(PID.TID 0000.0001) System time: 1.0000000000000009E-002 |
3931 |
(PID.TID 0000.0001) Wall clock time: 2.2483825683593750E-002 |
3932 |
(PID.TID 0000.0001) No. starts: 12 |
3933 |
(PID.TID 0000.0001) No. stops: 12 |
3934 |
(PID.TID 0000.0001) Seconds in section "SEAICE_MODEL [DO_OCEANIC_PHYS]": |
3935 |
(PID.TID 0000.0001) User time: 180.55000000000004 |
3936 |
(PID.TID 0000.0001) System time: 0.19000000000000000 |
3937 |
(PID.TID 0000.0001) Wall clock time: 180.79792118072510 |
3938 |
(PID.TID 0000.0001) No. starts: 12 |
3939 |
(PID.TID 0000.0001) No. stops: 12 |
3940 |
(PID.TID 0000.0001) Seconds in section "SEAICE_DYNSOLVER [SEAICE_MODEL]": |
3941 |
(PID.TID 0000.0001) User time: 180.39000000000001 |
3942 |
(PID.TID 0000.0001) System time: 0.19000000000000000 |
3943 |
(PID.TID 0000.0001) Wall clock time: 180.64591073989868 |
3944 |
(PID.TID 0000.0001) No. starts: 12 |
3945 |
(PID.TID 0000.0001) No. stops: 12 |
3946 |
(PID.TID 0000.0001) Seconds in section "BLOCKING_EXCHANGES [FORWARD_STEP]": |
3947 |
(PID.TID 0000.0001) User time: 0.0000000000000000 |
3948 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3949 |
(PID.TID 0000.0001) Wall clock time: 4.7216415405273438E-003 |
3950 |
(PID.TID 0000.0001) No. starts: 24 |
3951 |
(PID.TID 0000.0001) No. stops: 24 |
3952 |
(PID.TID 0000.0001) Seconds in section "THERMODYNAMICS [FORWARD_STEP]": |
3953 |
(PID.TID 0000.0001) User time: 0.0000000000000000 |
3954 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3955 |
(PID.TID 0000.0001) Wall clock time: 5.4106712341308594E-003 |
3956 |
(PID.TID 0000.0001) No. starts: 12 |
3957 |
(PID.TID 0000.0001) No. stops: 12 |
3958 |
(PID.TID 0000.0001) Seconds in section "TRC_CORRECTION_STEP [FORWARD_STEP]": |
3959 |
(PID.TID 0000.0001) User time: 0.0000000000000000 |
3960 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3961 |
(PID.TID 0000.0001) Wall clock time: 1.0514259338378906E-004 |
3962 |
(PID.TID 0000.0001) No. starts: 12 |
3963 |
(PID.TID 0000.0001) No. stops: 12 |
3964 |
(PID.TID 0000.0001) Seconds in section "MONITOR [FORWARD_STEP]": |
3965 |
(PID.TID 0000.0001) User time: 0.0000000000000000 |
3966 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3967 |
(PID.TID 0000.0001) Wall clock time: 9.4890594482421875E-005 |
3968 |
(PID.TID 0000.0001) No. starts: 12 |
3969 |
(PID.TID 0000.0001) No. stops: 12 |
3970 |
(PID.TID 0000.0001) Seconds in section "DO_THE_MODEL_IO [FORWARD_STEP]": |
3971 |
(PID.TID 0000.0001) User time: 8.9999999999946567E-002 |
3972 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3973 |
(PID.TID 0000.0001) Wall clock time: 8.2524776458740234E-002 |
3974 |
(PID.TID 0000.0001) No. starts: 12 |
3975 |
(PID.TID 0000.0001) No. stops: 12 |
3976 |
(PID.TID 0000.0001) Seconds in section "DO_WRITE_PICKUP [FORWARD_STEP]": |
3977 |
(PID.TID 0000.0001) User time: 1.0000000000019327E-002 |
3978 |
(PID.TID 0000.0001) System time: 0.0000000000000000 |
3979 |
(PID.TID 0000.0001) Wall clock time: 5.4347515106201172E-003 |
3980 |
(PID.TID 0000.0001) No. starts: 12 |
3981 |
(PID.TID 0000.0001) No. stops: 12 |
3982 |
(PID.TID 0000.0001) // ====================================================== |
3983 |
(PID.TID 0000.0001) // Tile <-> Tile communication statistics |
3984 |
(PID.TID 0000.0001) // ====================================================== |
3985 |
(PID.TID 0000.0001) // o Tile number: 000001 |
3986 |
(PID.TID 0000.0001) // No. X exchanges = 0 |
3987 |
(PID.TID 0000.0001) // Max. X spins = 0 |
3988 |
(PID.TID 0000.0001) // Min. X spins = 1000000000 |
3989 |
(PID.TID 0000.0001) // Total. X spins = 0 |
3990 |
(PID.TID 0000.0001) // Avg. X spins = 0.00E+00 |
3991 |
(PID.TID 0000.0001) // No. Y exchanges = 0 |
3992 |
(PID.TID 0000.0001) // Max. Y spins = 0 |
3993 |
(PID.TID 0000.0001) // Min. Y spins = 1000000000 |
3994 |
(PID.TID 0000.0001) // Total. Y spins = 0 |
3995 |
(PID.TID 0000.0001) // Avg. Y spins = 0.00E+00 |
3996 |
(PID.TID 0000.0001) // o Tile number: 000002 |
3997 |
(PID.TID 0000.0001) // No. X exchanges = 0 |
3998 |
(PID.TID 0000.0001) // Max. X spins = 0 |
3999 |
(PID.TID 0000.0001) // Min. X spins = 1000000000 |
4000 |
(PID.TID 0000.0001) // Total. X spins = 0 |
4001 |
(PID.TID 0000.0001) // Avg. X spins = 0.00E+00 |
4002 |
(PID.TID 0000.0001) // No. Y exchanges = 0 |
4003 |
(PID.TID 0000.0001) // Max. Y spins = 0 |
4004 |
(PID.TID 0000.0001) // Min. Y spins = 1000000000 |
4005 |
(PID.TID 0000.0001) // Total. Y spins = 0 |
4006 |
(PID.TID 0000.0001) // Avg. Y spins = 0.00E+00 |
4007 |
(PID.TID 0000.0001) // o Tile number: 000003 |
4008 |
(PID.TID 0000.0001) // No. X exchanges = 0 |
4009 |
(PID.TID 0000.0001) // Max. X spins = 0 |
4010 |
(PID.TID 0000.0001) // Min. X spins = 1000000000 |
4011 |
(PID.TID 0000.0001) // Total. X spins = 0 |
4012 |
(PID.TID 0000.0001) // Avg. X spins = 0.00E+00 |
4013 |
(PID.TID 0000.0001) // No. Y exchanges = 0 |
4014 |
(PID.TID 0000.0001) // Max. Y spins = 0 |
4015 |
(PID.TID 0000.0001) // Min. Y spins = 1000000000 |
4016 |
(PID.TID 0000.0001) // Total. Y spins = 0 |
4017 |
(PID.TID 0000.0001) // Avg. Y spins = 0.00E+00 |
4018 |
(PID.TID 0000.0001) // o Tile number: 000004 |
4019 |
(PID.TID 0000.0001) // No. X exchanges = 0 |
4020 |
(PID.TID 0000.0001) // Max. X spins = 0 |
4021 |
(PID.TID 0000.0001) // Min. X spins = 1000000000 |
4022 |
(PID.TID 0000.0001) // Total. X spins = 0 |
4023 |
(PID.TID 0000.0001) // Avg. X spins = 0.00E+00 |
4024 |
(PID.TID 0000.0001) // No. Y exchanges = 0 |
4025 |
(PID.TID 0000.0001) // Max. Y spins = 0 |
4026 |
(PID.TID 0000.0001) // Min. Y spins = 1000000000 |
4027 |
(PID.TID 0000.0001) // Total. Y spins = 0 |
4028 |
(PID.TID 0000.0001) // Avg. Y spins = 0.00E+00 |
4029 |
(PID.TID 0000.0001) // o Thread number: 000001 |
4030 |
(PID.TID 0000.0001) // No. barriers = 44620 |
4031 |
(PID.TID 0000.0001) // Max. barrier spins = 1 |
4032 |
(PID.TID 0000.0001) // Min. barrier spins = 1 |
4033 |
(PID.TID 0000.0001) // Total barrier spins = 44620 |
4034 |
(PID.TID 0000.0001) // Avg. barrier spins = 1.00E+00 |
4035 |
PROGRAM MAIN: Execution ended Normally |