/[MITgcm]/MITgcm/verification/seaice_itd/results/output.txt
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Contents of /MITgcm/verification/seaice_itd/results/output.txt

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Revision 1.8 - (show annotations) (download)
Mon Nov 28 15:52:40 2016 UTC (7 years, 5 months ago) by mlosch
Branch: MAIN
CVS Tags: checkpoint66g, checkpoint66f, checkpoint66e, checkpoint66d, checkpoint66c, checkpoint66b, checkpoint66o, checkpoint66n, checkpoint66m, checkpoint66l, checkpoint66k, checkpoint66j, checkpoint66i, checkpoint66h, HEAD
Changes since 1.7: +1568 -413 lines
File MIME type: text/plain 
- change one verification experiment to test linear remapping scheme
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: checkpoint66a
9 (PID.TID 0000.0001) // Build user: mlosch
10 (PID.TID 0000.0001) // Build host: bkli04l006
11 (PID.TID 0000.0001) // Build date: Wed Nov 16 18:31:22 CET 2016
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=1.e-4,
132 (PID.TID 0000.0001) > f0=0.e-4,
133 (PID.TID 0000.0001) > beta=0.,
134 (PID.TID 0000.0001) > useJamartWetPoints=.TRUE.,
135 (PID.TID 0000.0001) > rigidLid=.FALSE.,
136 (PID.TID 0000.0001) > implicitFreeSurface=.TRUE.,
137 (PID.TID 0000.0001) >#exactConserv=.TRUE.,
138 (PID.TID 0000.0001) > convertFW2Salt=-1,
139 (PID.TID 0000.0001) > readBinaryPrec=64,
140 (PID.TID 0000.0001) > writeBinaryPrec=64,
141 (PID.TID 0000.0001) >#globalFiles=.TRUE.,
142 (PID.TID 0000.0001) > useSingleCpuIO=.TRUE.,
143 (PID.TID 0000.0001) >#debugLevel=4,
144 (PID.TID 0000.0001) > /
145 (PID.TID 0000.0001) >
146 (PID.TID 0000.0001) ># Elliptic solver parameters
147 (PID.TID 0000.0001) > &PARM02
148 (PID.TID 0000.0001) > cg2dMaxIters=500,
149 (PID.TID 0000.0001) > cg2dTargetResidual=1.E-12,
150 (PID.TID 0000.0001) > /
151 (PID.TID 0000.0001) >
152 (PID.TID 0000.0001) ># Time stepping parameters
153 (PID.TID 0000.0001) > &PARM03
154 (PID.TID 0000.0001) > startTime=0.0,
155 (PID.TID 0000.0001) >#endTime=432000.,
156 (PID.TID 0000.0001) > deltaT=1800.0,
157 (PID.TID 0000.0001) > abEps=0.1,
158 (PID.TID 0000.0001) > forcing_In_AB = .FALSE.,
159 (PID.TID 0000.0001) > pChkptFreq=3600000.,
160 (PID.TID 0000.0001) > dumpFreq = 864000.,
161 (PID.TID 0000.0001) > monitorSelect=2,
162 (PID.TID 0000.0001) > nTimeSteps=12,
163 (PID.TID 0000.0001) > monitorFreq=21600.,
164 (PID.TID 0000.0001) > /
165 (PID.TID 0000.0001) >
166 (PID.TID 0000.0001) ># Gridding parameters
167 (PID.TID 0000.0001) > &PARM04
168 (PID.TID 0000.0001) > usingCartesianGrid=.TRUE.,
169 (PID.TID 0000.0001) > delX=80*5.E3,
170 (PID.TID 0000.0001) > delY=42*5.E3,
171 (PID.TID 0000.0001) > ygOrigin=-110.E3,
172 (PID.TID 0000.0001) >#delR= 20., 30., 50.,
173 (PID.TID 0000.0001) > delR= 10.,
174 (PID.TID 0000.0001) > /
175 (PID.TID 0000.0001) >
176 (PID.TID 0000.0001) ># Input datasets
177 (PID.TID 0000.0001) > &PARM05
178 (PID.TID 0000.0001) > bathyFile = 'bathy_3c.bin',
179 (PID.TID 0000.0001) > uVelInitFile = 'uVel_3c0.bin',
180 (PID.TID 0000.0001) > vVelInitFile = 'vVel_3c0.bin',
181 (PID.TID 0000.0001) > pSurfInitFile = 'eta_3c0.bin',
182 (PID.TID 0000.0001) >#uVelInitFile = 'uVel_3c1.bin',
183 (PID.TID 0000.0001) >#vVelInitFile = 'vVel_3c1.bin',
184 (PID.TID 0000.0001) >#pSurfInitFile = 'eta_3c1.bin',
185 (PID.TID 0000.0001) >#bathyFile = 'channel.bin',
186 (PID.TID 0000.0001) >#uVelInitFile = 'const+40.bin',
187 (PID.TID 0000.0001) >#vVelInitFile = 'const-10.bin',
188 (PID.TID 0000.0001) > /
189 (PID.TID 0000.0001)
190 (PID.TID 0000.0001) INI_PARMS ; starts to read PARM01
191 (PID.TID 0000.0001) INI_PARMS ; read PARM01 : OK
192 (PID.TID 0000.0001) INI_PARMS ; starts to read PARM02
193 (PID.TID 0000.0001) INI_PARMS ; read PARM02 : OK
194 (PID.TID 0000.0001) INI_PARMS ; starts to read PARM03
195 (PID.TID 0000.0001) INI_PARMS ; read PARM03 : OK
196 (PID.TID 0000.0001) INI_PARMS ; starts to read PARM04
197 (PID.TID 0000.0001) INI_PARMS ; read PARM04 : OK
198 (PID.TID 0000.0001) INI_PARMS ; starts to read PARM05
199 (PID.TID 0000.0001) INI_PARMS ; read PARM05 : OK
200 (PID.TID 0000.0001) INI_PARMS: finished reading file "data"
201 (PID.TID 0000.0001) PACKAGES_BOOT: opening data.pkg
202 (PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.pkg
203 (PID.TID 0000.0001) // =======================================================
204 (PID.TID 0000.0001) // Parameter file "data.pkg"
205 (PID.TID 0000.0001) // =======================================================
206 (PID.TID 0000.0001) ># Packages
207 (PID.TID 0000.0001) > &PACKAGES
208 (PID.TID 0000.0001) > useEXF = .TRUE.,
209 (PID.TID 0000.0001) > useSEAICE = .TRUE.,
210 (PID.TID 0000.0001) ># useThSIce = .TRUE.,
211 (PID.TID 0000.0001) > useDiagnostics=.TRUE.,
212 (PID.TID 0000.0001) > /
213 (PID.TID 0000.0001)
214 (PID.TID 0000.0001) PACKAGES_BOOT: finished reading data.pkg
215 (PID.TID 0000.0001) PACKAGES_BOOT: On/Off package Summary
216 -------- pkgs with a standard "usePKG" On/Off switch in "data.pkg": --------
217 pkg/cal compiled and used ( useCAL = T )
218 pkg/exf compiled and used ( useEXF = T )
219 pkg/seaice compiled and used ( useSEAICE = 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 and used ( useGAD = T )
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) >#usePW79thermodynamics=.FALSE.,
359 (PID.TID 0000.0001) > SEAICErestoreUnderIce=.TRUE.,
360 (PID.TID 0000.0001) > SEAICE_no_Slip = .FALSE.,
361 (PID.TID 0000.0001) > LSR_ERROR = 1.E-12,
362 (PID.TID 0000.0001) > SEAICElinearIterMax= 1500,
363 (PID.TID 0000.0001) > LSR_mixIniGuess = 1,
364 (PID.TID 0000.0001) > SEAICEadvScheme = 77,
365 (PID.TID 0000.0001) > AreaFile = 'const100.bin',
366 (PID.TID 0000.0001) > HeffFile = 'heff_quartic.bin',
367 (PID.TID 0000.0001) > HsnowFile = 'const_00.bin',
368 (PID.TID 0000.0001) > SEAICEwriteState = .TRUE.,
369 (PID.TID 0000.0001) > SEAICE_monFreq = 1800.,
370 (PID.TID 0000.0001) ># ridging
371 (PID.TID 0000.0001) > SEAICEsimpleRidging = .FALSE.,
372 (PID.TID 0000.0001) > useHibler79IceStrength = .FALSE.,
373 (PID.TID 0000.0001) > SEAICE_cf = 2.,
374 (PID.TID 0000.0001) > SEAICEredistFunc = 0,
375 (PID.TID 0000.0001) > SEAICEpartFunc = 0,
376 (PID.TID 0000.0001) > /
377 (PID.TID 0000.0001) >
378 (PID.TID 0000.0001) > &SEAICE_PARM03
379 (PID.TID 0000.0001) > /
380 (PID.TID 0000.0001)
381 (PID.TID 0000.0001) SEAICE_READPARMS: finished reading data.seaice
382 (PID.TID 0000.0001) DIAGNOSTICS_READPARMS: opening data.diagnostics
383 (PID.TID 0000.0001) OPEN_COPY_DATA_FILE: opening file data.diagnostics
384 (PID.TID 0000.0001) // =======================================================
385 (PID.TID 0000.0001) // Parameter file "data.diagnostics"
386 (PID.TID 0000.0001) // =======================================================
387 (PID.TID 0000.0001) ># Diagnostic Package Choices
388 (PID.TID 0000.0001) >#--------------------
389 (PID.TID 0000.0001) ># dumpAtLast (logical): always write output at the end of simulation (default=F)
390 (PID.TID 0000.0001) ># diag_mnc (logical): write to NetCDF files (default=useMNC)
391 (PID.TID 0000.0001) >#--for each output-stream:
392 (PID.TID 0000.0001) ># fileName(n) : prefix of the output file name (max 80c long) for outp.stream n
393 (PID.TID 0000.0001) ># frequency(n):< 0 : write snap-shot output every |frequency| seconds
394 (PID.TID 0000.0001) ># > 0 : write time-average output every frequency seconds
395 (PID.TID 0000.0001) ># timePhase(n) : write at time = timePhase + multiple of |frequency|
396 (PID.TID 0000.0001) ># averagingFreq : frequency (in s) for periodic averaging interval
397 (PID.TID 0000.0001) ># averagingPhase : phase (in s) for periodic averaging interval
398 (PID.TID 0000.0001) ># repeatCycle : number of averaging intervals in 1 cycle
399 (PID.TID 0000.0001) ># levels(:,n) : list of levels to write to file (Notes: declared as REAL)
400 (PID.TID 0000.0001) ># when this entry is missing, select all common levels of this list
401 (PID.TID 0000.0001) ># fields(:,n) : list of selected diagnostics fields (8.c) in outp.stream n
402 (PID.TID 0000.0001) ># (see "available_diagnostics.log" file for the full list of diags)
403 (PID.TID 0000.0001) ># missing_value(n) : missing value for real-type fields in output file "n"
404 (PID.TID 0000.0001) ># fileFlags(n) : specific code (8c string) for output file "n"
405 (PID.TID 0000.0001) >#--------------------
406 (PID.TID 0000.0001) ># This example dumps EXF diagnostics as snapshot after 10 time-steps
407 (PID.TID 0000.0001) ># Note: EXF air-sea fluxes over Sea-Ice are wrong
408 (PID.TID 0000.0001) > &DIAGNOSTICS_LIST
409 (PID.TID 0000.0001) > dumpAtLast = .TRUE.,
410 (PID.TID 0000.0001) >#--
411 (PID.TID 0000.0001) > fields(1:11,1) = 'EXFtaux ','EXFtauy ','EXFqnet ','EXFempmr',
412 (PID.TID 0000.0001) > 'EXFhl ','EXFhs ','EXFswnet','EXFlwnet',
413 (PID.TID 0000.0001) > 'EXFuwind','EXFvwind','EXFatemp',
414 (PID.TID 0000.0001) ># fileName(1) = 'exfDiag',
415 (PID.TID 0000.0001) > frequency(1) = 86400.,
416 (PID.TID 0000.0001) >
417 (PID.TID 0000.0001) > fields(1:4,2) = 'SIuice ','SIvice ','SIheff ',
418 (PID.TID 0000.0001) > 'SIarea ',
419 (PID.TID 0000.0001) ># fileName(2) = 'iceDiag',
420 (PID.TID 0000.0001) > frequency(2) = 86400.,
421 (PID.TID 0000.0001) > missing_value(2) = -999.,
422 (PID.TID 0000.0001) >
423 (PID.TID 0000.0001) > fields(1:4,3) = 'SIuice ','SIvice ','SIheff ',
424 (PID.TID 0000.0001) > 'SIarea ',
425 (PID.TID 0000.0001) > fileName(3) = 'snapshot',
426 (PID.TID 0000.0001) > frequency(3) = -86400.,
427 (PID.TID 0000.0001) > timePhase(3) = 3600.,
428 (PID.TID 0000.0001) > missing_value(3) = -999.,
429 (PID.TID 0000.0001) > /
430 (PID.TID 0000.0001) >
431 (PID.TID 0000.0001) >#--------------------
432 (PID.TID 0000.0001) ># Parameter for Diagnostics of per level statistics:
433 (PID.TID 0000.0001) >#--------------------
434 (PID.TID 0000.0001) ># diagSt_mnc (logical): write stat-diags to NetCDF files (default=diag_mnc)
435 (PID.TID 0000.0001) ># diagSt_regMaskFile : file containing the region-mask to read-in
436 (PID.TID 0000.0001) ># nSetRegMskFile : number of region-mask sets within the region-mask file
437 (PID.TID 0000.0001) ># set_regMask(i) : region-mask set-index that identifies the region "i"
438 (PID.TID 0000.0001) ># val_regMask(i) : region "i" identifier value in the region mask
439 (PID.TID 0000.0001) >#--for each output-stream:
440 (PID.TID 0000.0001) ># stat_fName(n) : prefix of the output file name (max 80c long) for outp.stream n
441 (PID.TID 0000.0001) ># stat_freq(n):< 0 : write snap-shot output every |stat_freq| seconds
442 (PID.TID 0000.0001) ># > 0 : write time-average output every stat_freq seconds
443 (PID.TID 0000.0001) ># stat_phase(n) : write at time = stat_phase + multiple of |stat_freq|
444 (PID.TID 0000.0001) ># stat_region(:,n) : list of "regions" (default: 1 region only=global)
445 (PID.TID 0000.0001) ># stat_fields(:,n) : list of selected diagnostics fields (8.c) in outp.stream n
446 (PID.TID 0000.0001) ># (see "available_diagnostics.log" file for the full list of diags)
447 (PID.TID 0000.0001) >#--------------------
448 (PID.TID 0000.0001) > &DIAG_STATIS_PARMS
449 (PID.TID 0000.0001) > stat_fields(1:5,1) = 'SIarea ','SIheff ','SIhsnow ',
450 (PID.TID 0000.0001) > 'SIuice ','SIvice ',
451 (PID.TID 0000.0001) > stat_fName(1) = 'iceStDiag',
452 (PID.TID 0000.0001) > stat_freq(1) = 7200.,
453 (PID.TID 0000.0001) > stat_phase(1) = 1800.,
454 (PID.TID 0000.0001) > /
455 (PID.TID 0000.0001)
456 (PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "diagnostics_list": start
457 (PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "diagnostics_list": OK
458 (PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "DIAG_STATIS_PARMS": start
459 (PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "DIAG_STATIS_PARMS": OK
460 (PID.TID 0000.0001) DIAGNOSTICS_READPARMS: global parameter summary:
461 (PID.TID 0000.0001) dumpAtLast = /* always write time-ave diags at the end */
462 (PID.TID 0000.0001) T
463 (PID.TID 0000.0001) ;
464 (PID.TID 0000.0001) diag_mnc = /* write NetCDF output files */
465 (PID.TID 0000.0001) F
466 (PID.TID 0000.0001) ;
467 (PID.TID 0000.0001) useMissingValue = /* put MissingValue where mask = 0 */
468 (PID.TID 0000.0001) F
469 (PID.TID 0000.0001) ;
470 (PID.TID 0000.0001) diagCG_maxIters = /* max number of iters in diag_cg2d */
471 (PID.TID 0000.0001) 500
472 (PID.TID 0000.0001) ;
473 (PID.TID 0000.0001) diagCG_resTarget = /* residual target for diag_cg2d */
474 (PID.TID 0000.0001) 1.000000000000000E-12
475 (PID.TID 0000.0001) ;
476 (PID.TID 0000.0001) diagCG_pcOffDFac = /* preconditioner off-diagonal factor */
477 (PID.TID 0000.0001) 9.611687812379854E-01
478 (PID.TID 0000.0001) ;
479 (PID.TID 0000.0001) -----------------------------------------------------
480 (PID.TID 0000.0001) DIAGNOSTICS_READPARMS: active diagnostics summary:
481 (PID.TID 0000.0001) -----------------------------------------------------
482 (PID.TID 0000.0001) Creating Output Stream: snapshot
483 (PID.TID 0000.0001) Output Frequency: -86400.000000 ; Phase: 3600.000000
484 (PID.TID 0000.0001) Averaging Freq.: 0.000000 , Phase: 0.000000 , Cycle: 1
485 (PID.TID 0000.0001) missing value: -9.990000000000E+02
486 (PID.TID 0000.0001) Levels: will be set later
487 (PID.TID 0000.0001) Fields: SIuice SIvice SIheff SIarea
488 (PID.TID 0000.0001) -----------------------------------------------------
489 (PID.TID 0000.0001) DIAGNOSTICS_READPARMS: statistics diags. summary:
490 (PID.TID 0000.0001) Creating Stats. Output Stream: iceStDiag
491 (PID.TID 0000.0001) Output Frequency: 7200.000000 ; Phase: 1800.000000
492 (PID.TID 0000.0001) Regions: 0
493 (PID.TID 0000.0001) Fields: SIarea SIheff SIhsnow SIuice SIvice
494 (PID.TID 0000.0001) -----------------------------------------------------
495 (PID.TID 0000.0001)
496 (PID.TID 0000.0001) SET_PARMS: done
497 (PID.TID 0000.0001) Enter INI_VERTICAL_GRID: setInterFDr= T ; setCenterDr= F
498 (PID.TID 0000.0001) %MON XC_max = 3.9750000000000E+05
499 (PID.TID 0000.0001) %MON XC_min = 2.5000000000000E+03
500 (PID.TID 0000.0001) %MON XC_mean = 2.0000000000000E+05
501 (PID.TID 0000.0001) %MON XC_sd = 1.1546103238755E+05
502 (PID.TID 0000.0001) %MON XG_max = 3.9500000000000E+05
503 (PID.TID 0000.0001) %MON XG_min = 0.0000000000000E+00
504 (PID.TID 0000.0001) %MON XG_mean = 1.9750000000000E+05
505 (PID.TID 0000.0001) %MON XG_sd = 1.1546103238755E+05
506 (PID.TID 0000.0001) %MON DXC_max = 5.0000000000000E+03
507 (PID.TID 0000.0001) %MON DXC_min = 5.0000000000000E+03
508 (PID.TID 0000.0001) %MON DXC_mean = 5.0000000000000E+03
509 (PID.TID 0000.0001) %MON DXC_sd = 0.0000000000000E+00
510 (PID.TID 0000.0001) %MON DXF_max = 5.0000000000000E+03
511 (PID.TID 0000.0001) %MON DXF_min = 5.0000000000000E+03
512 (PID.TID 0000.0001) %MON DXF_mean = 5.0000000000000E+03
513 (PID.TID 0000.0001) %MON DXF_sd = 0.0000000000000E+00
514 (PID.TID 0000.0001) %MON DXG_max = 5.0000000000000E+03
515 (PID.TID 0000.0001) %MON DXG_min = 5.0000000000000E+03
516 (PID.TID 0000.0001) %MON DXG_mean = 5.0000000000000E+03
517 (PID.TID 0000.0001) %MON DXG_sd = 0.0000000000000E+00
518 (PID.TID 0000.0001) %MON DXV_max = 5.0000000000000E+03
519 (PID.TID 0000.0001) %MON DXV_min = 5.0000000000000E+03
520 (PID.TID 0000.0001) %MON DXV_mean = 5.0000000000000E+03
521 (PID.TID 0000.0001) %MON DXV_sd = 0.0000000000000E+00
522 (PID.TID 0000.0001) %MON YC_max = 9.7500000000000E+04
523 (PID.TID 0000.0001) %MON YC_min = -1.0750000000000E+05
524 (PID.TID 0000.0001) %MON YC_mean = -5.0000000000000E+03
525 (PID.TID 0000.0001) %MON YC_sd = 6.0604592785256E+04
526 (PID.TID 0000.0001) %MON YG_max = 9.5000000000000E+04
527 (PID.TID 0000.0001) %MON YG_min = -1.1000000000000E+05
528 (PID.TID 0000.0001) %MON YG_mean = -7.5000000000000E+03
529 (PID.TID 0000.0001) %MON YG_sd = 6.0604592785256E+04
530 (PID.TID 0000.0001) %MON DYC_max = 5.0000000000000E+03
531 (PID.TID 0000.0001) %MON DYC_min = 5.0000000000000E+03
532 (PID.TID 0000.0001) %MON DYC_mean = 5.0000000000000E+03
533 (PID.TID 0000.0001) %MON DYC_sd = 0.0000000000000E+00
534 (PID.TID 0000.0001) %MON DYF_max = 5.0000000000000E+03
535 (PID.TID 0000.0001) %MON DYF_min = 5.0000000000000E+03
536 (PID.TID 0000.0001) %MON DYF_mean = 5.0000000000000E+03
537 (PID.TID 0000.0001) %MON DYF_sd = 0.0000000000000E+00
538 (PID.TID 0000.0001) %MON DYG_max = 5.0000000000000E+03
539 (PID.TID 0000.0001) %MON DYG_min = 5.0000000000000E+03
540 (PID.TID 0000.0001) %MON DYG_mean = 5.0000000000000E+03
541 (PID.TID 0000.0001) %MON DYG_sd = 0.0000000000000E+00
542 (PID.TID 0000.0001) %MON DYU_max = 5.0000000000000E+03
543 (PID.TID 0000.0001) %MON DYU_min = 5.0000000000000E+03
544 (PID.TID 0000.0001) %MON DYU_mean = 5.0000000000000E+03
545 (PID.TID 0000.0001) %MON DYU_sd = 0.0000000000000E+00
546 (PID.TID 0000.0001) %MON RA_max = 2.5000000000000E+07
547 (PID.TID 0000.0001) %MON RA_min = 2.5000000000000E+07
548 (PID.TID 0000.0001) %MON RA_mean = 2.5000000000000E+07
549 (PID.TID 0000.0001) %MON RA_sd = 3.7252902984619E-09
550 (PID.TID 0000.0001) %MON RAW_max = 2.5000000000000E+07
551 (PID.TID 0000.0001) %MON RAW_min = 2.5000000000000E+07
552 (PID.TID 0000.0001) %MON RAW_mean = 2.5000000000000E+07
553 (PID.TID 0000.0001) %MON RAW_sd = 3.7252902984619E-09
554 (PID.TID 0000.0001) %MON RAS_max = 2.5000000000000E+07
555 (PID.TID 0000.0001) %MON RAS_min = 2.5000000000000E+07
556 (PID.TID 0000.0001) %MON RAS_mean = 2.5000000000000E+07
557 (PID.TID 0000.0001) %MON RAS_sd = 3.7252902984619E-09
558 (PID.TID 0000.0001) %MON RAZ_max = 2.5000000000000E+07
559 (PID.TID 0000.0001) %MON RAZ_min = 2.5000000000000E+07
560 (PID.TID 0000.0001) %MON RAZ_mean = 2.5000000000000E+07
561 (PID.TID 0000.0001) %MON RAZ_sd = 3.7252902984619E-09
562 (PID.TID 0000.0001) %MON AngleCS_max = 1.0000000000000E+00
563 (PID.TID 0000.0001) %MON AngleCS_min = 1.0000000000000E+00
564 (PID.TID 0000.0001) %MON AngleCS_mean = 1.0000000000000E+00
565 (PID.TID 0000.0001) %MON AngleCS_sd = 0.0000000000000E+00
566 (PID.TID 0000.0001) %MON AngleSN_max = 0.0000000000000E+00
567 (PID.TID 0000.0001) %MON AngleSN_min = 0.0000000000000E+00
568 (PID.TID 0000.0001) %MON AngleSN_mean = 0.0000000000000E+00
569 (PID.TID 0000.0001) %MON AngleSN_sd = 0.0000000000000E+00
570 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: bathy_3c.bin
571 (PID.TID 0000.0001) // =======================================================
572 (PID.TID 0000.0001) // Field Model R_low (ini_masks_etc)
573 (PID.TID 0000.0001) // CMIN = -1.000000000000000E+01
574 (PID.TID 0000.0001) // CMAX = -1.000000000000000E+01
575 (PID.TID 0000.0001) // CINT = 0.000000000000000E+00
576 (PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+
577 (PID.TID 0000.0001) // 0.0: .
578 (PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):( -2: 83: 1)
579 (PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):( 45: -2: -1)
580 (PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):( 1: 1: 1)
581 (PID.TID 0000.0001) // =======================================================
582 (PID.TID 0000.0001) // =======================================================
583 (PID.TID 0000.0001) // END OF FIELD =
584 (PID.TID 0000.0001) // =======================================================
585 (PID.TID 0000.0001)
586 (PID.TID 0000.0001) // =======================================================
587 (PID.TID 0000.0001) // Field Model Ro_surf (ini_masks_etc)
588 (PID.TID 0000.0001) // CMIN = 1.000000000000000E+32
589 (PID.TID 0000.0001) // CMAX = -1.000000000000000E+32
590 (PID.TID 0000.0001) // CINT = 0.000000000000000E+00
591 (PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+
592 (PID.TID 0000.0001) // 0.0: .
593 (PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):( -2: 83: 1)
594 (PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):( 45: -2: -1)
595 (PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):( 1: 1: 1)
596 (PID.TID 0000.0001) // =======================================================
597 (PID.TID 0000.0001) // =======================================================
598 (PID.TID 0000.0001) // END OF FIELD =
599 (PID.TID 0000.0001) // =======================================================
600 (PID.TID 0000.0001)
601 (PID.TID 0000.0001) // =======================================================
602 (PID.TID 0000.0001) // Field hFacC at iteration 0
603 (PID.TID 0000.0001) // CMIN = 1.000000000000000E+00
604 (PID.TID 0000.0001) // CMAX = 1.000000000000000E+00
605 (PID.TID 0000.0001) // CINT = 0.000000000000000E+00
606 (PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+
607 (PID.TID 0000.0001) // 0.0: .
608 (PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):( -2: 83: 1)
609 (PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):( 45: -2: -1)
610 (PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):( 1: 1: 1)
611 (PID.TID 0000.0001) // =======================================================
612 (PID.TID 0000.0001) // =======================================================
613 (PID.TID 0000.0001) // END OF FIELD =
614 (PID.TID 0000.0001) // =======================================================
615 (PID.TID 0000.0001)
616 (PID.TID 0000.0001) // =======================================================
617 (PID.TID 0000.0001) // Field hFacW at iteration 0
618 (PID.TID 0000.0001) // CMIN = 1.000000000000000E+00
619 (PID.TID 0000.0001) // CMAX = 1.000000000000000E+00
620 (PID.TID 0000.0001) // CINT = 0.000000000000000E+00
621 (PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+
622 (PID.TID 0000.0001) // 0.0: .
623 (PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):( -2: 83: 1)
624 (PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):( 45: -2: -1)
625 (PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):( 1: 1: 1)
626 (PID.TID 0000.0001) // =======================================================
627 (PID.TID 0000.0001) // =======================================================
628 (PID.TID 0000.0001) // END OF FIELD =
629 (PID.TID 0000.0001) // =======================================================
630 (PID.TID 0000.0001)
631 (PID.TID 0000.0001) // =======================================================
632 (PID.TID 0000.0001) // Field hFacS at iteration 0
633 (PID.TID 0000.0001) // CMIN = 1.000000000000000E+00
634 (PID.TID 0000.0001) // CMAX = 1.000000000000000E+00
635 (PID.TID 0000.0001) // CINT = 0.000000000000000E+00
636 (PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+
637 (PID.TID 0000.0001) // 0.0: .
638 (PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):( -2: 83: 1)
639 (PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):( 45: -2: -1)
640 (PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):( 1: 1: 1)
641 (PID.TID 0000.0001) // =======================================================
642 (PID.TID 0000.0001) // =======================================================
643 (PID.TID 0000.0001) // END OF FIELD =
644 (PID.TID 0000.0001) // =======================================================
645 (PID.TID 0000.0001)
646 (PID.TID 0000.0001)
647 (PID.TID 0000.0001) // =======================================================
648 (PID.TID 0000.0001) // Calendar configuration >>> START <<<
649 (PID.TID 0000.0001) // =======================================================
650 (PID.TID 0000.0001)
651 (PID.TID 0000.0001) modelstart = /* Start time of the model integration [s] */
652 (PID.TID 0000.0001) 0.000000000000000E+00
653 (PID.TID 0000.0001) ;
654 (PID.TID 0000.0001) modelend = /* End time of the model integration [s] */
655 (PID.TID 0000.0001) 2.160000000000000E+04
656 (PID.TID 0000.0001) ;
657 (PID.TID 0000.0001) modelStep = /* Time interval for a model forward step [s] */
658 (PID.TID 0000.0001) 1.800000000000000E+03
659 (PID.TID 0000.0001) ;
660 (PID.TID 0000.0001) usingGregorianCalendar= /* Calendar Type: Gregorian Calendar */
661 (PID.TID 0000.0001) T
662 (PID.TID 0000.0001) ;
663 (PID.TID 0000.0001) usingJulianCalendar = /* Calendar Type: Julian Calendar */
664 (PID.TID 0000.0001) F
665 (PID.TID 0000.0001) ;
666 (PID.TID 0000.0001) usingNoLeapYearCal = /* Calendar Type: without Leap Year */
667 (PID.TID 0000.0001) F
668 (PID.TID 0000.0001) ;
669 (PID.TID 0000.0001) usingModelCalendar = /* Calendar Type: Model Calendar */
670 (PID.TID 0000.0001) F
671 (PID.TID 0000.0001) ;
672 (PID.TID 0000.0001) modelStartDate YYYYMMDD = /* Model start date YYYY-MM-DD */
673 (PID.TID 0000.0001) 19790101
674 (PID.TID 0000.0001) ;
675 (PID.TID 0000.0001) modelStartDate HHMMSS = /* Model start date HH-MM-SS */
676 (PID.TID 0000.0001) 0
677 (PID.TID 0000.0001) ;
678 (PID.TID 0000.0001) modelEndDate YYYYMMDD = /* Model end date YYYY-MM-DD */
679 (PID.TID 0000.0001) 19790101
680 (PID.TID 0000.0001) ;
681 (PID.TID 0000.0001) modelEndDate HHMMSS = /* Model end date HH-MM-SS */
682 (PID.TID 0000.0001) 60000
683 (PID.TID 0000.0001) ;
684 (PID.TID 0000.0001) intyears = /* Number of calendar years affected by the integration */
685 (PID.TID 0000.0001) 1
686 (PID.TID 0000.0001) ;
687 (PID.TID 0000.0001) intmonths= /* Number of calendar months affected by the integration */
688 (PID.TID 0000.0001) 1
689 (PID.TID 0000.0001) ;
690 (PID.TID 0000.0001) intdays = /* Number of calendar days affected by the integration */
691 (PID.TID 0000.0001) 1
692 (PID.TID 0000.0001) ;
693 (PID.TID 0000.0001) modelIter0 = /* Base timestep number */
694 (PID.TID 0000.0001) 0
695 (PID.TID 0000.0001) ;
696 (PID.TID 0000.0001) modelIterEnd = /* Final timestep number */
697 (PID.TID 0000.0001) 12
698 (PID.TID 0000.0001) ;
699 (PID.TID 0000.0001) modelIntSteps= /* Number of model timesteps */
700 (PID.TID 0000.0001) 12
701 (PID.TID 0000.0001) ;
702 (PID.TID 0000.0001)
703 (PID.TID 0000.0001) // =======================================================
704 (PID.TID 0000.0001) // Calendar configuration >>> END <<<
705 (PID.TID 0000.0001) // =======================================================
706 (PID.TID 0000.0001)
707 (PID.TID 0000.0001) GAD_INIT_FIXED: GAD_OlMinSize= 0 0 1
708 (PID.TID 0000.0001)
709 (PID.TID 0000.0001) // ===================================
710 (PID.TID 0000.0001) // GAD parameters :
711 (PID.TID 0000.0001) // ===================================
712 (PID.TID 0000.0001) tempAdvScheme = /* Temp. Horiz.Advection scheme selector */
713 (PID.TID 0000.0001) 2
714 (PID.TID 0000.0001) ;
715 (PID.TID 0000.0001) tempVertAdvScheme = /* Temp. Vert. Advection scheme selector */
716 (PID.TID 0000.0001) 2
717 (PID.TID 0000.0001) ;
718 (PID.TID 0000.0001) tempMultiDimAdvec = /* use Muti-Dim Advec method for Temp */
719 (PID.TID 0000.0001) F
720 (PID.TID 0000.0001) ;
721 (PID.TID 0000.0001) tempSOM_Advection = /* use 2nd Order Moment Advection for Temp */
722 (PID.TID 0000.0001) F
723 (PID.TID 0000.0001) ;
724 (PID.TID 0000.0001) AdamsBashforthGt = /* apply Adams-Bashforth extrapolation on Gt */
725 (PID.TID 0000.0001) T
726 (PID.TID 0000.0001) ;
727 (PID.TID 0000.0001) AdamsBashforth_T = /* apply Adams-Bashforth extrapolation on Temp */
728 (PID.TID 0000.0001) F
729 (PID.TID 0000.0001) ;
730 (PID.TID 0000.0001) saltAdvScheme = /* Salt. Horiz.advection scheme selector */
731 (PID.TID 0000.0001) 2
732 (PID.TID 0000.0001) ;
733 (PID.TID 0000.0001) saltVertAdvScheme = /* Salt. Vert. Advection scheme selector */
734 (PID.TID 0000.0001) 2
735 (PID.TID 0000.0001) ;
736 (PID.TID 0000.0001) saltMultiDimAdvec = /* use Muti-Dim Advec method for Salt */
737 (PID.TID 0000.0001) F
738 (PID.TID 0000.0001) ;
739 (PID.TID 0000.0001) saltSOM_Advection = /* use 2nd Order Moment Advection for Salt */
740 (PID.TID 0000.0001) F
741 (PID.TID 0000.0001) ;
742 (PID.TID 0000.0001) AdamsBashforthGs = /* apply Adams-Bashforth extrapolation on Gs */
743 (PID.TID 0000.0001) F
744 (PID.TID 0000.0001) ;
745 (PID.TID 0000.0001) AdamsBashforth_S = /* apply Adams-Bashforth extrapolation on Salt */
746 (PID.TID 0000.0001) F
747 (PID.TID 0000.0001) ;
748 (PID.TID 0000.0001) // ===================================
749 (PID.TID 0000.0001)
750 (PID.TID 0000.0001) // =======================================================
751 (PID.TID 0000.0001) // External forcing (EXF) configuration >>> START <<<
752 (PID.TID 0000.0001) // =======================================================
753 (PID.TID 0000.0001)
754 (PID.TID 0000.0001) EXF general parameters:
755 (PID.TID 0000.0001)
756 (PID.TID 0000.0001) exf_iprec = /* exf file precision */
757 (PID.TID 0000.0001) 64
758 (PID.TID 0000.0001) ;
759 (PID.TID 0000.0001) useExfYearlyFields = /* add extension _YEAR to input file names */
760 (PID.TID 0000.0001) F
761 (PID.TID 0000.0001) ;
762 (PID.TID 0000.0001) twoDigitYear = /* use 2-digit year extension */
763 (PID.TID 0000.0001) F
764 (PID.TID 0000.0001) ;
765 (PID.TID 0000.0001) useExfCheckRange = /* check for fields range */
766 (PID.TID 0000.0001) T
767 (PID.TID 0000.0001) ;
768 (PID.TID 0000.0001) exf_debugLev = /* select EXF-debug printing level */
769 (PID.TID 0000.0001) 2
770 (PID.TID 0000.0001) ;
771 (PID.TID 0000.0001) exf_monFreq = /* EXF monitor frequency [ s ] */
772 (PID.TID 0000.0001) 8.640000000000000E+07
773 (PID.TID 0000.0001) ;
774 (PID.TID 0000.0001) repeatPeriod = /* period for cycling forcing dataset [ s ] */
775 (PID.TID 0000.0001) 0.000000000000000E+00
776 (PID.TID 0000.0001) ;
777 (PID.TID 0000.0001) climTempFreeze= /* Minimum climatological temperature [deg.C] */
778 (PID.TID 0000.0001) -1.900000000000000E+00
779 (PID.TID 0000.0001) ;
780 (PID.TID 0000.0001) windStressMax = /* Maximum absolute windstress [ Pa ] */
781 (PID.TID 0000.0001) 2.000000000000000E+00
782 (PID.TID 0000.0001) ;
783 (PID.TID 0000.0001) stressIsOnCgrid = /* set u,v_stress on Arakawa C-grid */
784 (PID.TID 0000.0001) F
785 (PID.TID 0000.0001) ;
786 (PID.TID 0000.0001) rotateStressOnAgrid = /* rotate u,v_stress on Arakawa A-grid */
787 (PID.TID 0000.0001) F
788 (PID.TID 0000.0001) ;
789 (PID.TID 0000.0001) cen2kel = /* conversion of deg. Centigrade to Kelvin [K] */
790 (PID.TID 0000.0001) 2.731500000000000E+02
791 (PID.TID 0000.0001) ;
792 (PID.TID 0000.0001) gravity_mks= /* gravitational acceleration [m/s^2] */
793 (PID.TID 0000.0001) 9.810000000000000E+00
794 (PID.TID 0000.0001) ;
795 (PID.TID 0000.0001) atmrho = /* mean atmospheric density [kg/m^3] */
796 (PID.TID 0000.0001) 1.200000000000000E+00
797 (PID.TID 0000.0001) ;
798 (PID.TID 0000.0001) atmcp = /* mean atmospheric specific heat [J/kg/K] */
799 (PID.TID 0000.0001) 1.005000000000000E+03
800 (PID.TID 0000.0001) ;
801 (PID.TID 0000.0001) flamb = /* latent heat of evaporation [J/kg] */
802 (PID.TID 0000.0001) 2.500000000000000E+06
803 (PID.TID 0000.0001) ;
804 (PID.TID 0000.0001) flami = /* latent heat of pure-ice melting [J/kg] */
805 (PID.TID 0000.0001) 3.340000000000000E+05
806 (PID.TID 0000.0001) ;
807 (PID.TID 0000.0001) cvapor_fac = /* const. for Saturation calculation [?] */
808 (PID.TID 0000.0001) 6.403800000000000E+05
809 (PID.TID 0000.0001) ;
810 (PID.TID 0000.0001) cvapor_exp = /* const. for Saturation calculation [?] */
811 (PID.TID 0000.0001) 5.107400000000000E+03
812 (PID.TID 0000.0001) ;
813 (PID.TID 0000.0001) cvapor_fac_ice= /* const. for Saturation calculation [?] */
814 (PID.TID 0000.0001) 1.163780000000000E+07
815 (PID.TID 0000.0001) ;
816 (PID.TID 0000.0001) cvapor_exp_ice= /* const. for Saturation calculation [?] */
817 (PID.TID 0000.0001) 5.897800000000000E+03
818 (PID.TID 0000.0001) ;
819 (PID.TID 0000.0001) humid_fac = /* humidity coef. in virtual temp. [(kg/kg)^-1] */
820 (PID.TID 0000.0001) 6.060000000000000E-01
821 (PID.TID 0000.0001) ;
822 (PID.TID 0000.0001) gamma_blk = /* adiabatic lapse rate [?] */
823 (PID.TID 0000.0001) 1.000000000000000E-02
824 (PID.TID 0000.0001) ;
825 (PID.TID 0000.0001) saltsat = /* reduction of Qsat over salty water [-] */
826 (PID.TID 0000.0001) 9.800000000000000E-01
827 (PID.TID 0000.0001) ;
828 (PID.TID 0000.0001) noNegativeEvap = /* prevent negative Evaporation */
829 (PID.TID 0000.0001) F
830 (PID.TID 0000.0001) ;
831 (PID.TID 0000.0001) sstExtrapol = /* extrapolation coeff from lev. 1 & 2 to surf [-] */
832 (PID.TID 0000.0001) 0.000000000000000E+00
833 (PID.TID 0000.0001) ;
834 (PID.TID 0000.0001) cDrag_1 = /* coef used in drag calculation [?] */
835 (PID.TID 0000.0001) 2.700000000000000E-03
836 (PID.TID 0000.0001) ;
837 (PID.TID 0000.0001) cDrag_2 = /* coef used in drag calculation [?] */
838 (PID.TID 0000.0001) 1.420000000000000E-04
839 (PID.TID 0000.0001) ;
840 (PID.TID 0000.0001) cDrag_3 = /* coef used in drag calculation [?] */
841 (PID.TID 0000.0001) 7.640000000000000E-05
842 (PID.TID 0000.0001) ;
843 (PID.TID 0000.0001) cStanton_1 = /* coef used in Stanton number calculation [?] */
844 (PID.TID 0000.0001) 3.270000000000000E-02
845 (PID.TID 0000.0001) ;
846 (PID.TID 0000.0001) cStanton_2 = /* coef used in Stanton number calculation [?] */
847 (PID.TID 0000.0001) 1.800000000000000E-02
848 (PID.TID 0000.0001) ;
849 (PID.TID 0000.0001) cDalton = /* coef used in Dalton number calculation [?] */
850 (PID.TID 0000.0001) 3.460000000000000E-02
851 (PID.TID 0000.0001) ;
852 (PID.TID 0000.0001) exf_scal_BulkCdn= /* Drag coefficient scaling factor [-] */
853 (PID.TID 0000.0001) 1.000000000000000E+00
854 (PID.TID 0000.0001) ;
855 (PID.TID 0000.0001) zolmin = /* minimum stability parameter [?] */
856 (PID.TID 0000.0001) -1.000000000000000E+02
857 (PID.TID 0000.0001) ;
858 (PID.TID 0000.0001) psim_fac = /* coef used in turbulent fluxes calculation [-] */
859 (PID.TID 0000.0001) 5.000000000000000E+00
860 (PID.TID 0000.0001) ;
861 (PID.TID 0000.0001) zref = /* reference height [ m ] */
862 (PID.TID 0000.0001) 1.000000000000000E+01
863 (PID.TID 0000.0001) ;
864 (PID.TID 0000.0001) hu = /* height of mean wind [ m ] */
865 (PID.TID 0000.0001) 1.000000000000000E+01
866 (PID.TID 0000.0001) ;
867 (PID.TID 0000.0001) ht = /* height of mean temperature [ m ] */
868 (PID.TID 0000.0001) 2.000000000000000E+00
869 (PID.TID 0000.0001) ;
870 (PID.TID 0000.0001) hq = /* height of mean spec.humidity [ m ] */
871 (PID.TID 0000.0001) 2.000000000000000E+00
872 (PID.TID 0000.0001) ;
873 (PID.TID 0000.0001) uMin = /* minimum wind speed [m/s] */
874 (PID.TID 0000.0001) 5.000000000000000E-01
875 (PID.TID 0000.0001) ;
876 (PID.TID 0000.0001) useStabilityFct_overIce= /* transfert Coeffs over sea-ice depend on stability */
877 (PID.TID 0000.0001) F
878 (PID.TID 0000.0001) ;
879 (PID.TID 0000.0001) exf_iceCd = /* drag coefficient over sea-ice (fixed) [-] */
880 (PID.TID 0000.0001) 1.630000000000000E-03
881 (PID.TID 0000.0001) ;
882 (PID.TID 0000.0001) exf_iceCe = /* transfert coeff. over sea-ice, for Evap (fixed) [-] */
883 (PID.TID 0000.0001) 1.630000000000000E-03
884 (PID.TID 0000.0001) ;
885 (PID.TID 0000.0001) exf_iceCh = /* transfert coeff. over sea-ice, Sens.Heat.(fixed)[-] */
886 (PID.TID 0000.0001) 1.630000000000000E-03
887 (PID.TID 0000.0001) ;
888 (PID.TID 0000.0001) exf_albedo = /* Sea-water albedo [-] */
889 (PID.TID 0000.0001) 1.000000000000000E-01
890 (PID.TID 0000.0001) ;
891 (PID.TID 0000.0001) useExfZenAlbedo = /* Sea-water albedo varies with zenith angle */
892 (PID.TID 0000.0001) F
893 (PID.TID 0000.0001) ;
894 (PID.TID 0000.0001) select_ZenAlbedo = /* Sea-water albedo computation method */
895 (PID.TID 0000.0001) 0
896 (PID.TID 0000.0001) ;
897 (PID.TID 0000.0001) useExfZenIncoming = /* compute incoming solar radiation */
898 (PID.TID 0000.0001) F
899 (PID.TID 0000.0001) ;
900 (PID.TID 0000.0001) ocean_emissivity = /* longwave ocean-surface emissivity [-] */
901 (PID.TID 0000.0001) 9.700176366843034E-01
902 (PID.TID 0000.0001) ;
903 (PID.TID 0000.0001) ice_emissivity = /* longwave seaice emissivity [-] */
904 (PID.TID 0000.0001) 9.500000000000000E-01
905 (PID.TID 0000.0001) ;
906 (PID.TID 0000.0001) snow_emissivity = /* longwave snow emissivity [-] */
907 (PID.TID 0000.0001) 9.500000000000000E-01
908 (PID.TID 0000.0001) ;
909 (PID.TID 0000.0001)
910 (PID.TID 0000.0001) EXF main CPP flags:
911 (PID.TID 0000.0001)
912 (PID.TID 0000.0001) // USE_EXF_INTERPOLATION: NOT defined
913 (PID.TID 0000.0001) // ALLOW_ATM_TEMP: defined
914 (PID.TID 0000.0001) // ALLOW_ATM_WIND (useAtmWind): defined
915 (PID.TID 0000.0001) // ALLOW_DOWNWARD_RADIATION: defined
916 (PID.TID 0000.0001) // ALLOW_BULKFORMULAE: defined
917 (PID.TID 0000.0001)
918 (PID.TID 0000.0001) Net shortwave flux forcing starts at 0.
919 (PID.TID 0000.0001) Net shortwave flux forcing period is 0.
920 (PID.TID 0000.0001) Net shortwave flux forcing is read from file:
921 (PID.TID 0000.0001) >> <<
922 (PID.TID 0000.0001)
923 (PID.TID 0000.0001) Zonal wind forcing starts at 0.
924 (PID.TID 0000.0001) Zonal wind forcing period is 0.
925 (PID.TID 0000.0001) Zonal wind forcing is read from file:
926 (PID.TID 0000.0001) >> windx.bin <<
927 (PID.TID 0000.0001)
928 (PID.TID 0000.0001) Meridional wind forcing starts at 0.
929 (PID.TID 0000.0001) Meridional wind forcing period is 0.
930 (PID.TID 0000.0001) Meridional wind forcing is read from file:
931 (PID.TID 0000.0001) >> <<
932 (PID.TID 0000.0001)
933 (PID.TID 0000.0001) Atmospheric temperature starts at 0.
934 (PID.TID 0000.0001) Atmospheric temperature period is 0.
935 (PID.TID 0000.0001) Atmospheric temperature is read from file:
936 (PID.TID 0000.0001) >> tair_4x.bin <<
937 (PID.TID 0000.0001)
938 (PID.TID 0000.0001) Atmospheric specific humidity starts at 0.
939 (PID.TID 0000.0001) Atmospheric specific humidity period is 0.
940 (PID.TID 0000.0001) Atmospheric specific humidity is read from file:
941 (PID.TID 0000.0001) >> qa70_4x.bin <<
942 (PID.TID 0000.0001)
943 (PID.TID 0000.0001) Net longwave flux forcing starts at 0.
944 (PID.TID 0000.0001) Net longwave flux forcing period is 0.
945 (PID.TID 0000.0001) Net longwave flux forcing is read from file:
946 (PID.TID 0000.0001) >> <<
947 (PID.TID 0000.0001)
948 (PID.TID 0000.0001) Precipitation data set starts at 0.
949 (PID.TID 0000.0001) Precipitation data period is 0.
950 (PID.TID 0000.0001) Precipitation data is read from file:
951 (PID.TID 0000.0001) >> const_00.bin <<
952 (PID.TID 0000.0001)
953 (PID.TID 0000.0001) // EXF_READ_EVAP: NOT defined
954 (PID.TID 0000.0001)
955 (PID.TID 0000.0001) // ALLOW_RUNOFF: defined
956 (PID.TID 0000.0001) Runoff starts at 0.
957 (PID.TID 0000.0001) Runoff period is 0.
958 (PID.TID 0000.0001) Runoff is read from file:
959 (PID.TID 0000.0001) >> <<
960 (PID.TID 0000.0001) // ALLOW_RUNOFTEMP: NOT defined
961 (PID.TID 0000.0001)
962 (PID.TID 0000.0001) Downward shortwave flux forcing starts at 0.
963 (PID.TID 0000.0001) Downward shortwave flux forcing period is 0.
964 (PID.TID 0000.0001) Downward shortwave flux forcing is read from file:
965 (PID.TID 0000.0001) >> dsw_100.bin <<
966 (PID.TID 0000.0001)
967 (PID.TID 0000.0001) Downward longwave flux forcing starts at 0.
968 (PID.TID 0000.0001) Downward longwave flux forcing period is 0.
969 (PID.TID 0000.0001) Downward longwave flux forcing is read from file:
970 (PID.TID 0000.0001) >> dlw_250.bin <<
971 (PID.TID 0000.0001)
972 (PID.TID 0000.0001) Atmospheric pressure forcing starts at 0.
973 (PID.TID 0000.0001) Atmospheric pressure forcing period is 0.
974 (PID.TID 0000.0001) Atmospheric pressureforcing is read from file:
975 (PID.TID 0000.0001) >> <<
976 (PID.TID 0000.0001)
977 (PID.TID 0000.0001) // =======================================================
978 (PID.TID 0000.0001) // External forcing (EXF) climatology configuration :
979 (PID.TID 0000.0001) // =======================================================
980 (PID.TID 0000.0001)
981 (PID.TID 0000.0001) // ALLOW_CLIMSST_RELAXATION: defined
982 (PID.TID 0000.0001) // ALLOW_CLIMSSS_RELAXATION: defined
983 (PID.TID 0000.0001)
984 (PID.TID 0000.0001) Climatological SST starts at 0.
985 (PID.TID 0000.0001) Climatological SST period is 0.
986 (PID.TID 0000.0001) Climatological SST is read from file:
987 (PID.TID 0000.0001) >> tocn.bin <<
988 (PID.TID 0000.0001)
989 (PID.TID 0000.0001) Climatological SSS starts at 0.
990 (PID.TID 0000.0001) Climatological SSS period is 0.
991 (PID.TID 0000.0001) Climatological SSS is read from file:
992 (PID.TID 0000.0001) >> <<
993 (PID.TID 0000.0001)
994 (PID.TID 0000.0001) // =======================================================
995 (PID.TID 0000.0001) // External forcing (EXF) configuration >>> END <<<
996 (PID.TID 0000.0001) // =======================================================
997 (PID.TID 0000.0001)
998 (PID.TID 0000.0001) SEAICE_INIT_FIXED: 7 sea ice thickness categories
999 (PID.TID 0000.0001) SEAICE_INIT_FIXED: Hlimit = 0.00 0.46 0.96 1.57 2.40 3.74 6.13 999.9
1000 (PID.TID 0000.0001) // =======================================================
1001 (PID.TID 0000.0001) // Seaice configuration (SEAICE_PARM01) >>> START <<<
1002 (PID.TID 0000.0001) // =======================================================
1003 (PID.TID 0000.0001)
1004 (PID.TID 0000.0001) Seaice time stepping configuration > START <
1005 (PID.TID 0000.0001) ----------------------------------------------
1006 (PID.TID 0000.0001) SEAICE_deltaTtherm= /* thermodynamic timestep */
1007 (PID.TID 0000.0001) 1.800000000000000E+03
1008 (PID.TID 0000.0001) ;
1009 (PID.TID 0000.0001) SEAICE_deltaTdyn = /* dynamic timestep */
1010 (PID.TID 0000.0001) 1.800000000000000E+03
1011 (PID.TID 0000.0001) ;
1012 (PID.TID 0000.0001) SEAICE_deltaTevp = /* EVP timestep */
1013 (PID.TID 0000.0001) 1.234567000000000E+05
1014 (PID.TID 0000.0001) ;
1015 (PID.TID 0000.0001) SEAICEuseBDF2 = /* use backw. differencing for mom. eq. */
1016 (PID.TID 0000.0001) F
1017 (PID.TID 0000.0001) ;
1018 (PID.TID 0000.0001) SEAICErestoreUnderIce = /* restore T and S under ice */
1019 (PID.TID 0000.0001) T
1020 (PID.TID 0000.0001) ;
1021 (PID.TID 0000.0001)
1022 (PID.TID 0000.0001) Seaice dynamics configuration > START <
1023 (PID.TID 0000.0001) ------------------------------------------
1024 (PID.TID 0000.0001) SEAICEuseDYNAMICS = /* use dynamics */
1025 (PID.TID 0000.0001) T
1026 (PID.TID 0000.0001) ;
1027 (PID.TID 0000.0001) model grid type = /* type of sea ice model grid */
1028 (PID.TID 0000.0001) 'C-GRID'
1029 (PID.TID 0000.0001) ;
1030 (PID.TID 0000.0001) SEAICEuseStrImpCpl = /* use strongly implicit coupling */
1031 (PID.TID 0000.0001) F
1032 (PID.TID 0000.0001) ;
1033 (PID.TID 0000.0001) SEAICEusePicardAsPrecon = /* Picard as preconditioner */
1034 (PID.TID 0000.0001) F
1035 (PID.TID 0000.0001) ;
1036 (PID.TID 0000.0001) SEAICEuseLSR = /* use default Picard-LSR solver */
1037 (PID.TID 0000.0001) T
1038 (PID.TID 0000.0001) ;
1039 (PID.TID 0000.0001) SEAICEuseKrylov = /* use Picard-Krylov solver */
1040 (PID.TID 0000.0001) F
1041 (PID.TID 0000.0001) ;
1042 (PID.TID 0000.0001) SEAICEuseEVP = /* use EVP solver rather than LSR */
1043 (PID.TID 0000.0001) F
1044 (PID.TID 0000.0001) ;
1045 (PID.TID 0000.0001) SEAICEuseJFNK = /* use JFNK solver */
1046 (PID.TID 0000.0001) F
1047 (PID.TID 0000.0001) ;
1048 (PID.TID 0000.0001) SEAICEuseFREEDRIFT = /* use free drift solution */
1049 (PID.TID 0000.0001) F
1050 (PID.TID 0000.0001) ;
1051 (PID.TID 0000.0001) OCEAN_drag = /* air-ocean drag coefficient */
1052 (PID.TID 0000.0001) 1.000000000000000E-03
1053 (PID.TID 0000.0001) ;
1054 (PID.TID 0000.0001) SEAICE_drag = /* air-ice drag coefficient */
1055 (PID.TID 0000.0001) 2.000000000000000E-03
1056 (PID.TID 0000.0001) ;
1057 (PID.TID 0000.0001) SEAICE_drag_south = /* Southern Ocean SEAICE_drag */
1058 (PID.TID 0000.0001) 2.000000000000000E-03
1059 (PID.TID 0000.0001) ;
1060 (PID.TID 0000.0001) SEAICE_waterDrag = /* water-ice drag * density */
1061 (PID.TID 0000.0001) 5.500000000000000E+00
1062 (PID.TID 0000.0001) ;
1063 (PID.TID 0000.0001) SEAICE_waterDrag_south = /* Southern Ocean waterDrag */
1064 (PID.TID 0000.0001) 5.500000000000000E+00
1065 (PID.TID 0000.0001) ;
1066 (PID.TID 0000.0001) SEAICEuseTilt = /* include surface tilt in dyna. */
1067 (PID.TID 0000.0001) T
1068 (PID.TID 0000.0001) ;
1069 (PID.TID 0000.0001) SEAICEuseTEM = /* use truncated ellipse rheology */
1070 (PID.TID 0000.0001) F
1071 (PID.TID 0000.0001) ;
1072 (PID.TID 0000.0001) SEAICE_strength = /* sea-ice strength Pstar */
1073 (PID.TID 0000.0001) 2.750000000000000E+04
1074 (PID.TID 0000.0001) ;
1075 (PID.TID 0000.0001) SEAICE_cStar = /* sea-ice strength parameter cStar */
1076 (PID.TID 0000.0001) 2.000000000000000E+01
1077 (PID.TID 0000.0001) ;
1078 (PID.TID 0000.0001) SEAICEpressReplFac= /* press. replacement method factor */
1079 (PID.TID 0000.0001) 1.000000000000000E+00
1080 (PID.TID 0000.0001) ;
1081 (PID.TID 0000.0001) SEAICE_tensilFac = /* sea-ice tensile strength factor */
1082 (PID.TID 0000.0001) 0.000000000000000E+00
1083 (PID.TID 0000.0001) ;
1084 (PID.TID 0000.0001) SEAICE_tensilDepth= /* crit. depth for tensile strength */
1085 (PID.TID 0000.0001) 0.000000000000000E+00
1086 (PID.TID 0000.0001) ;
1087 (PID.TID 0000.0001) SEAICEpresH0 = /* sea-ice strength Heff threshold */
1088 (PID.TID 0000.0001) 1.000000000000000E+00
1089 (PID.TID 0000.0001) ;
1090 (PID.TID 0000.0001) SEAICEpresPow0 = /* exponent for Heff<SEAICEpresH0 */
1091 (PID.TID 0000.0001) 1
1092 (PID.TID 0000.0001) ;
1093 (PID.TID 0000.0001) SEAICEpresPow1 = /* exponent for Heff>SEAICEpresH0 */
1094 (PID.TID 0000.0001) 1
1095 (PID.TID 0000.0001) ;
1096 (PID.TID 0000.0001) SEAICEetaZmethod = /* method computing eta at Z-point */
1097 (PID.TID 0000.0001) 0
1098 (PID.TID 0000.0001) ;
1099 (PID.TID 0000.0001) SEAICE_zetaMin = /* lower bound for viscosity */
1100 (PID.TID 0000.0001) 0.000000000000000E+00
1101 (PID.TID 0000.0001) ;
1102 (PID.TID 0000.0001) SEAICE_eccen = /* elliptical yield curve eccent */
1103 (PID.TID 0000.0001) 2.000000000000000E+00
1104 (PID.TID 0000.0001) ;
1105 (PID.TID 0000.0001) SEAICEstressFactor = /* wind stress scaling factor */
1106 (PID.TID 0000.0001) 1.000000000000000E+00
1107 (PID.TID 0000.0001) ;
1108 (PID.TID 0000.0001) SEAICE_airTurnAngle = /* air-ice turning angle */
1109 (PID.TID 0000.0001) 0.000000000000000E+00
1110 (PID.TID 0000.0001) ;
1111 (PID.TID 0000.0001) SEAICE_waterTurnAngle = /* ice-water turning angle */
1112 (PID.TID 0000.0001) 0.000000000000000E+00
1113 (PID.TID 0000.0001) ;
1114 (PID.TID 0000.0001) SEAICEuseMetricTerms = /* use metric terms */
1115 (PID.TID 0000.0001) T
1116 (PID.TID 0000.0001) ;
1117 (PID.TID 0000.0001) SEAICE_no_slip = /* no slip boundary conditions */
1118 (PID.TID 0000.0001) F
1119 (PID.TID 0000.0001) ;
1120 (PID.TID 0000.0001) SEAICE_clipVeloctities = /* impose max. vels. */
1121 (PID.TID 0000.0001) F
1122 (PID.TID 0000.0001) ;
1123 (PID.TID 0000.0001) useHB87stressCoupling = /* altern. ice-ocean stress */
1124 (PID.TID 0000.0001) F
1125 (PID.TID 0000.0001) ;
1126 (PID.TID 0000.0001) SEAICEscaleSurfStress = /* scale atm. and ocean-surface stress with AREA */
1127 (PID.TID 0000.0001) F
1128 (PID.TID 0000.0001) ;
1129 (PID.TID 0000.0001) SEAICE_maskRHS = /* mask RHS of solver */
1130 (PID.TID 0000.0001) F
1131 (PID.TID 0000.0001) ;
1132 (PID.TID 0000.0001) LSR_mixIniGuess = /* mix free-drift sol. into LSR initial Guess */
1133 (PID.TID 0000.0001) 1
1134 (PID.TID 0000.0001) ;
1135 (PID.TID 0000.0001) SEAICE_LSRrelaxU = /* LSR solver: relaxation parameter */
1136 (PID.TID 0000.0001) 9.500000000000000E-01
1137 (PID.TID 0000.0001) ;
1138 (PID.TID 0000.0001) SEAICE_LSRrelaxV = /* LSR solver: relaxation parameter */
1139 (PID.TID 0000.0001) 9.500000000000000E-01
1140 (PID.TID 0000.0001) ;
1141 (PID.TID 0000.0001) LSR_ERROR = /* sets accuracy of LSR solver */
1142 (PID.TID 0000.0001) 1.000000000000000E-12
1143 (PID.TID 0000.0001) ;
1144 (PID.TID 0000.0001) SOLV_NCHECK = /* test interval for LSR solver */
1145 (PID.TID 0000.0001) 2
1146 (PID.TID 0000.0001) ;
1147 (PID.TID 0000.0001) SEAICEuseMultiTileSolver = /* use full domain tri-diag solver */
1148 (PID.TID 0000.0001) F
1149 (PID.TID 0000.0001) ;
1150 (PID.TID 0000.0001) SEAICE_OLx = /* overlap for LSR/preconditioner */
1151 (PID.TID 0000.0001) 0
1152 (PID.TID 0000.0001) ;
1153 (PID.TID 0000.0001) SEAICE_OLy = /* overlap for LSR/preconditioner */
1154 (PID.TID 0000.0001) 0
1155 (PID.TID 0000.0001) ;
1156 (PID.TID 0000.0001) SEAICEnonLinIterMax = /* max. number of nonlinear solver steps */
1157 (PID.TID 0000.0001) 2
1158 (PID.TID 0000.0001) ;
1159 (PID.TID 0000.0001) SEAICElinearIterMax = /* max. number of linear solver steps */
1160 (PID.TID 0000.0001) 1500
1161 (PID.TID 0000.0001) ;
1162 (PID.TID 0000.0001) SEAICEnonLinTol = /* non-linear solver tolerance */
1163 (PID.TID 0000.0001) 0.000000000000000E+00
1164 (PID.TID 0000.0001) ;
1165 (PID.TID 0000.0001)
1166 (PID.TID 0000.0001) Seaice advection diffusion config, > START <
1167 (PID.TID 0000.0001) -----------------------------------------------
1168 (PID.TID 0000.0001) SEAICEadvHeff = /* advect effective ice thickness */
1169 (PID.TID 0000.0001) T
1170 (PID.TID 0000.0001) ;
1171 (PID.TID 0000.0001) SEAICEadvArea = /* advect fractional ice area */
1172 (PID.TID 0000.0001) T
1173 (PID.TID 0000.0001) ;
1174 (PID.TID 0000.0001) SEAICEadvSnow = /* advect snow layer together with ice */
1175 (PID.TID 0000.0001) T
1176 (PID.TID 0000.0001) ;
1177 (PID.TID 0000.0001) SEAICEadvScheme = /* advection scheme for ice */
1178 (PID.TID 0000.0001) 77
1179 (PID.TID 0000.0001) ;
1180 (PID.TID 0000.0001) SEAICEadvSchArea = /* advection scheme for area */
1181 (PID.TID 0000.0001) 77
1182 (PID.TID 0000.0001) ;
1183 (PID.TID 0000.0001) SEAICEadvSchHeff = /* advection scheme for thickness */
1184 (PID.TID 0000.0001) 77
1185 (PID.TID 0000.0001) ;
1186 (PID.TID 0000.0001) SEAICEadvSchSnow = /* advection scheme for snow */
1187 (PID.TID 0000.0001) 77
1188 (PID.TID 0000.0001) ;
1189 (PID.TID 0000.0001) SEAICEdiffKhArea = /* diffusivity (m^2/s) for area */
1190 (PID.TID 0000.0001) 0.000000000000000E+00
1191 (PID.TID 0000.0001) ;
1192 (PID.TID 0000.0001) SEAICEdiffKhHeff = /* diffusivity (m^2/s) for heff */
1193 (PID.TID 0000.0001) 0.000000000000000E+00
1194 (PID.TID 0000.0001) ;
1195 (PID.TID 0000.0001) SEAICEdiffKhSnow = /* diffusivity (m^2/s) for snow */
1196 (PID.TID 0000.0001) 0.000000000000000E+00
1197 (PID.TID 0000.0001) ;
1198 (PID.TID 0000.0001) DIFF1 = /* parameter used in advect.F [m/s] */
1199 (PID.TID 0000.0001) 0.000000000000000E+00
1200 (PID.TID 0000.0001) ;
1201 (PID.TID 0000.0001)
1202 (PID.TID 0000.0001) Seaice thermodynamics configuration > START <
1203 (PID.TID 0000.0001) -----------------------------------------------
1204 (PID.TID 0000.0001) SEAICE_rhoIce = /* density of sea ice (kg/m3) */
1205 (PID.TID 0000.0001) 9.100000000000000E+02
1206 (PID.TID 0000.0001) ;
1207 (PID.TID 0000.0001) SEAICE_rhoSnow = /* density of snow (kg/m3) */
1208 (PID.TID 0000.0001) 3.300000000000000E+02
1209 (PID.TID 0000.0001) ;
1210 (PID.TID 0000.0001) SEAICE_rhoAir = /* density of air (kg/m3) */
1211 (PID.TID 0000.0001) 1.200000000000000E+00
1212 (PID.TID 0000.0001) ;
1213 (PID.TID 0000.0001) usePW79thermodynamics = /* default 0-layer TD */
1214 (PID.TID 0000.0001) T
1215 (PID.TID 0000.0001) ;
1216 (PID.TID 0000.0001) SEAICE_lhEvap = /* latent heat of evaporation */
1217 (PID.TID 0000.0001) 2.500000000000000E+06
1218 (PID.TID 0000.0001) ;
1219 (PID.TID 0000.0001) SEAICE_lhFusion = /* latent heat of fusion */
1220 (PID.TID 0000.0001) 3.340000000000000E+05
1221 (PID.TID 0000.0001) ;
1222 (PID.TID 0000.0001) SEAICE_mcPheePiston = /* turbulent flux "piston velocity" a la McPhee (m/s) */
1223 (PID.TID 0000.0001) 8.749999999999999E-04
1224 (PID.TID 0000.0001) ;
1225 (PID.TID 0000.0001) SEAICE_mcPheeTaper = /* tapering of turbulent flux (0.< <1.) for AREA=1. */
1226 (PID.TID 0000.0001) 0.000000000000000E+00
1227 (PID.TID 0000.0001) ;
1228 (PID.TID 0000.0001) SEAICE_mcPheeStepFunc = /* replace linear tapering with step funct. */
1229 (PID.TID 0000.0001) F
1230 (PID.TID 0000.0001) ;
1231 (PID.TID 0000.0001) SEAICE_frazilFrac = /* frazil (T<tempFrz) to seaice conversion rate (0.< <1.) */
1232 (PID.TID 0000.0001) 1.000000000000000E+00
1233 (PID.TID 0000.0001) ;
1234 (PID.TID 0000.0001) SEAICE_tempFrz0 = /* freezing temp. of sea water (intercept) */
1235 (PID.TID 0000.0001) 9.010000000000000E-02
1236 (PID.TID 0000.0001) ;
1237 (PID.TID 0000.0001) SEAICE_dTempFrz_dS= /* freezing temp. of sea water (slope) */
1238 (PID.TID 0000.0001) -5.750000000000000E-02
1239 (PID.TID 0000.0001) ;
1240 (PID.TID 0000.0001) SEAICE_growMeltByConv = /* grow,melt by vert. conv. */
1241 (PID.TID 0000.0001) F
1242 (PID.TID 0000.0001) ;
1243 (PID.TID 0000.0001) SEAICE_doOpenWaterGrowth = /* grow by open water */
1244 (PID.TID 0000.0001) T
1245 (PID.TID 0000.0001) ;
1246 (PID.TID 0000.0001) SEAICE_doOpenWaterMelt = /* melt by open water */
1247 (PID.TID 0000.0001) F
1248 (PID.TID 0000.0001) ;
1249 (PID.TID 0000.0001) SEAICE_areaGainFormula = /* ice cover gain formula (1,2)*/
1250 (PID.TID 0000.0001) 1
1251 (PID.TID 0000.0001) 1=from growth by ATM
1252 (PID.TID 0000.0001) 2=from predicted growth by ATM
1253 (PID.TID 0000.0001) ;
1254 (PID.TID 0000.0001) SEAICE_areaLossFormula = /* ice cover loss formula (1,2)*/
1255 (PID.TID 0000.0001) 1
1256 (PID.TID 0000.0001) 1=from all but only melt conributions by ATM and OCN
1257 (PID.TID 0000.0001) 2=from net melt-grow>0 by ATM and OCN
1258 (PID.TID 0000.0001) 3=from predicted melt by ATM
1259 (PID.TID 0000.0001) ;
1260 (PID.TID 0000.0001) HO = /* nominal thickness of new ice */
1261 (PID.TID 0000.0001) 5.000000000000000E-01
1262 (PID.TID 0000.0001) ;
1263 (PID.TID 0000.0001) HO_south = /* Southern Ocean HO */
1264 (PID.TID 0000.0001) 5.000000000000000E-01
1265 (PID.TID 0000.0001) ;
1266 (PID.TID 0000.0001) SEAICE_area_max = /* set to les than 1. to mimic open leads */
1267 (PID.TID 0000.0001) 1.000000000000000E+00
1268 (PID.TID 0000.0001) ;
1269 (PID.TID 0000.0001) SEAICE_salt0 = /* constant sea ice salinity */
1270 (PID.TID 0000.0001) 0.000000000000000E+00
1271 (PID.TID 0000.0001) ;
1272 (PID.TID 0000.0001) SEAICE_salinityTracer = /* test SITR varia. salinity */
1273 (PID.TID 0000.0001) F
1274 (PID.TID 0000.0001) ;
1275 (PID.TID 0000.0001) SEAICEuseFlooding = /* turn submerged snow into ice */
1276 (PID.TID 0000.0001) T
1277 (PID.TID 0000.0001) ;
1278 (PID.TID 0000.0001)
1279 (PID.TID 0000.0001) Seaice air-sea fluxes configuration, > START <
1280 (PID.TID 0000.0001) -----------------------------------------------
1281 (PID.TID 0000.0001) SEAICEheatConsFix = /* accound for ocn<->seaice advect. heat flux */
1282 (PID.TID 0000.0001) F
1283 (PID.TID 0000.0001) ;
1284 (PID.TID 0000.0001) nITD = /* number of ice thickness categories */
1285 (PID.TID 0000.0001) 7
1286 (PID.TID 0000.0001) ;
1287 (PID.TID 0000.0001) SEAICEuseLinRemapITD = /* select linear remapping scheme for ITD */
1288 (PID.TID 0000.0001) T
1289 (PID.TID 0000.0001) ;
1290 (PID.TID 0000.0001) useHibler79IceStrength = /* select ice strength parameterizationd */
1291 (PID.TID 0000.0001) F
1292 (PID.TID 0000.0001) ;
1293 (PID.TID 0000.0001) SEAICEsimpleRidging = /* select ridging scheme */
1294 (PID.TID 0000.0001) F
1295 (PID.TID 0000.0001) ;
1296 (PID.TID 0000.0001) SEAICEpartFunc = /* select ridging participation function */
1297 (PID.TID 0000.0001) 0
1298 (PID.TID 0000.0001) ;
1299 (PID.TID 0000.0001) SEAICEredistFunc = /* select ridging redistribution function */
1300 (PID.TID 0000.0001) 0
1301 (PID.TID 0000.0001) ;
1302 (PID.TID 0000.0001) SEAICE_cf = /* ice strength parameter */
1303 (PID.TID 0000.0001) 2.000000000000000E+00
1304 (PID.TID 0000.0001) ;
1305 (PID.TID 0000.0001) SEAICEshearParm = /* amount of energy lost to shear */
1306 (PID.TID 0000.0001) 5.000000000000000E-01
1307 (PID.TID 0000.0001) ;
1308 (PID.TID 0000.0001) SEAICEgStar = /* ridging parameter */
1309 (PID.TID 0000.0001) 1.500000000000000E-01
1310 (PID.TID 0000.0001) ;
1311 (PID.TID 0000.0001) SEAICEhStar = /* ridging parameter */
1312 (PID.TID 0000.0001) 2.500000000000000E+01
1313 (PID.TID 0000.0001) ;
1314 (PID.TID 0000.0001) SEAICEaStar = /* ridging parameter */
1315 (PID.TID 0000.0001) 5.000000000000000E-02
1316 (PID.TID 0000.0001) ;
1317 (PID.TID 0000.0001) SEAICEmuRidging = /* ridging parameter */
1318 (PID.TID 0000.0001) 3.000000000000000E+00
1319 (PID.TID 0000.0001) ;
1320 (PID.TID 0000.0001) SEAICEmaxRaft = /* ridging parameter */
1321 (PID.TID 0000.0001) 1.000000000000000E+00
1322 (PID.TID 0000.0001) ;
1323 (PID.TID 0000.0001) SEAICEsnowFracRidge = /* fraction of snow remaining on ridges */
1324 (PID.TID 0000.0001) 5.000000000000000E-01
1325 (PID.TID 0000.0001) ;
1326 (PID.TID 0000.0001) SEAICE_PDF = /* sea-ice distribution (-) */
1327 (PID.TID 0000.0001) 1.000000000000000E+00, /* K = 1 */
1328 (PID.TID 0000.0001) 6 @ 0.000000000000000E+00 /* K = 2: 7 */
1329 (PID.TID 0000.0001) ;
1330 (PID.TID 0000.0001) IMAX_TICE = /* iterations for ice surface temp */
1331 (PID.TID 0000.0001) 10
1332 (PID.TID 0000.0001) ;
1333 (PID.TID 0000.0001) postSolvTempIter= /* flux calculation after surf. temp iter */
1334 (PID.TID 0000.0001) 2
1335 (PID.TID 0000.0001) ;
1336 (PID.TID 0000.0001) SEAICE_dryIceAlb = /* winter albedo */
1337 (PID.TID 0000.0001) 7.500000000000000E-01
1338 (PID.TID 0000.0001) ;
1339 (PID.TID 0000.0001) SEAICE_wetIceAlb = /* summer albedo */
1340 (PID.TID 0000.0001) 6.600000000000000E-01
1341 (PID.TID 0000.0001) ;
1342 (PID.TID 0000.0001) SEAICE_drySnowAlb = /* dry snow albedo */
1343 (PID.TID 0000.0001) 8.400000000000000E-01
1344 (PID.TID 0000.0001) ;
1345 (PID.TID 0000.0001) SEAICE_wetSnowAlb = /* wet snow albedo */
1346 (PID.TID 0000.0001) 7.000000000000000E-01
1347 (PID.TID 0000.0001) ;
1348 (PID.TID 0000.0001) SEAICE_dryIceAlb_south = /* Southern Ocean dryIceAlb */
1349 (PID.TID 0000.0001) 7.500000000000000E-01
1350 (PID.TID 0000.0001) ;
1351 (PID.TID 0000.0001) SEAICE_wetIceAlb_south = /* Southern Ocean wetIceAlb */
1352 (PID.TID 0000.0001) 6.600000000000000E-01
1353 (PID.TID 0000.0001) ;
1354 (PID.TID 0000.0001) SEAICE_drySnowAlb_south= /* Southern Ocean drySnowAlb */
1355 (PID.TID 0000.0001) 8.400000000000000E-01
1356 (PID.TID 0000.0001) ;
1357 (PID.TID 0000.0001) SEAICE_wetSnowAlb_south= /* Southern Ocean wetSnowAlb */
1358 (PID.TID 0000.0001) 7.000000000000000E-01
1359 (PID.TID 0000.0001) ;
1360 (PID.TID 0000.0001) SEAICE_wetAlbTemp= /* Temp (o.C) threshold for wet-albedo */
1361 (PID.TID 0000.0001) -1.000000000000000E-03
1362 (PID.TID 0000.0001) ;
1363 (PID.TID 0000.0001) SEAICE_snow_emiss = /* snow emissivity */
1364 (PID.TID 0000.0001) 9.500000000000000E-01
1365 (PID.TID 0000.0001) ;
1366 (PID.TID 0000.0001) SEAICE_ice_emiss = /* seaice emissivity */
1367 (PID.TID 0000.0001) 9.500000000000000E-01
1368 (PID.TID 0000.0001) ;
1369 (PID.TID 0000.0001) SEAICE_cpAir = /* heat capacity of air */
1370 (PID.TID 0000.0001) 1.005000000000000E+03
1371 (PID.TID 0000.0001) ;
1372 (PID.TID 0000.0001) SEAICE_dalton = /* constant dalton number */
1373 (PID.TID 0000.0001) 1.750000000000000E-03
1374 (PID.TID 0000.0001) ;
1375 (PID.TID 0000.0001) SEAICE_iceConduct = /* sea-ice conductivity */
1376 (PID.TID 0000.0001) 2.165600000000000E+00
1377 (PID.TID 0000.0001) ;
1378 (PID.TID 0000.0001) SEAICE_snowConduct= /* snow conductivity */
1379 (PID.TID 0000.0001) 3.100000000000000E-01
1380 (PID.TID 0000.0001) ;
1381 (PID.TID 0000.0001) SEAICE_snowThick = /* cutoff snow thickness (for albedo) */
1382 (PID.TID 0000.0001) 1.500000000000000E-01
1383 (PID.TID 0000.0001) ;
1384 (PID.TID 0000.0001) SEAICE_shortwave = /* penetration shortwave radiation */
1385 (PID.TID 0000.0001) 3.000000000000000E-01
1386 (PID.TID 0000.0001) ;
1387 (PID.TID 0000.0001) useMaykutSatVapPoly = /* use Maykut Polynomial for Sat.Vap.Pr */
1388 (PID.TID 0000.0001) F
1389 (PID.TID 0000.0001) ;
1390 (PID.TID 0000.0001) MIN_ATEMP = /* minimum air temperature */
1391 (PID.TID 0000.0001) -5.000000000000000E+01
1392 (PID.TID 0000.0001) ;
1393 (PID.TID 0000.0001) MIN_LWDOWN = /* minimum downward longwave */
1394 (PID.TID 0000.0001) 6.000000000000000E+01
1395 (PID.TID 0000.0001) ;
1396 (PID.TID 0000.0001) MIN_TICE = /* minimum ice temperature */
1397 (PID.TID 0000.0001) -5.000000000000000E+01
1398 (PID.TID 0000.0001) ;
1399 (PID.TID 0000.0001)
1400 (PID.TID 0000.0001) Seaice initialization and IO config., > START <
1401 (PID.TID 0000.0001) -------------------------------------------------
1402 (PID.TID 0000.0001) SEAICE_initialHEFF= /* initial sea-ice thickness */
1403 (PID.TID 0000.0001) 0.000000000000000E+00
1404 (PID.TID 0000.0001) ;
1405 (PID.TID 0000.0001) AreaFile = /* Initial ice concentration File */
1406 (PID.TID 0000.0001) 'const100.bin'
1407 (PID.TID 0000.0001) ;
1408 (PID.TID 0000.0001) HeffFile = /* Initial effective ice thickness File */
1409 (PID.TID 0000.0001) 'heff_quartic.bin'
1410 (PID.TID 0000.0001) ;
1411 (PID.TID 0000.0001) HsnowFile = /* Initial snow thickness File */
1412 (PID.TID 0000.0001) 'const_00.bin'
1413 (PID.TID 0000.0001) ;
1414 (PID.TID 0000.0001) uIceFile = /* Initial U-ice velocity File */
1415 (PID.TID 0000.0001) ''
1416 (PID.TID 0000.0001) ;
1417 (PID.TID 0000.0001) vIceFile = /* Initial V-ice velocity File */
1418 (PID.TID 0000.0001) ''
1419 (PID.TID 0000.0001) ;
1420 (PID.TID 0000.0001) SEAICEwriteState = /* write sea ice state to file */
1421 (PID.TID 0000.0001) T
1422 (PID.TID 0000.0001) ;
1423 (PID.TID 0000.0001) SEAICE_monFreq = /* monitor frequency */
1424 (PID.TID 0000.0001) 1.800000000000000E+03
1425 (PID.TID 0000.0001) ;
1426 (PID.TID 0000.0001) SEAICE_dumpFreq = /* dump frequency */
1427 (PID.TID 0000.0001) 8.640000000000000E+05
1428 (PID.TID 0000.0001) ;
1429 (PID.TID 0000.0001) SEAICE_taveFreq = /* time-averaging frequency */
1430 (PID.TID 0000.0001) 0.000000000000000E+00
1431 (PID.TID 0000.0001) ;
1432 (PID.TID 0000.0001) SEAICE_mon_stdio = /* write monitor to std-outp */
1433 (PID.TID 0000.0001) T
1434 (PID.TID 0000.0001) ;
1435 (PID.TID 0000.0001) SEAICE_dump_mdsio = /* write snap-shot using MDSIO */
1436 (PID.TID 0000.0001) T
1437 (PID.TID 0000.0001) ;
1438 (PID.TID 0000.0001) SEAICE_tave_mdsio = /* write TimeAverage using MDSIO */
1439 (PID.TID 0000.0001) T
1440 (PID.TID 0000.0001) ;
1441 (PID.TID 0000.0001)
1442 (PID.TID 0000.0001) Seaice regularization numbers, > START <
1443 (PID.TID 0000.0001) -----------------------------------------------
1444 (PID.TID 0000.0001) SEAICE_deltaMin = /* reduce singularities in Delta */
1445 (PID.TID 0000.0001) 1.000000000000000E-10
1446 (PID.TID 0000.0001) ;
1447 (PID.TID 0000.0001) SEAICE_EPS = /* small number */
1448 (PID.TID 0000.0001) 1.000000000000000E-10
1449 (PID.TID 0000.0001) ;
1450 (PID.TID 0000.0001) SEAICE_EPS_SQ = /* small number squared */
1451 (PID.TID 0000.0001) 1.000000000000000E-20
1452 (PID.TID 0000.0001) ;
1453 (PID.TID 0000.0001) SEAICE_area_reg = /* reduce derivative singularities */
1454 (PID.TID 0000.0001) 1.000000000000000E-05
1455 (PID.TID 0000.0001) ;
1456 (PID.TID 0000.0001) SEAICE_hice_reg = /* reduce derivative singularities */
1457 (PID.TID 0000.0001) 5.000000000000000E-02
1458 (PID.TID 0000.0001) ;
1459 (PID.TID 0000.0001) SEAICE_area_floor = /* reduce derivative singularities */
1460 (PID.TID 0000.0001) 1.000000000000000E-05
1461 (PID.TID 0000.0001) ;
1462 (PID.TID 0000.0001)
1463 (PID.TID 0000.0001) // =======================================================
1464 (PID.TID 0000.0001) // Seaice configuration (SEAICE_PARM01) >>> END <<<
1465 (PID.TID 0000.0001) // =======================================================
1466 (PID.TID 0000.0001)
1467 (PID.TID 0000.0001) ------------------------------------------------------------
1468 (PID.TID 0000.0001) DIAGNOSTICS_SET_LEVELS: done
1469 (PID.TID 0000.0001) Total Nb of available Diagnostics: ndiagt= 217
1470 (PID.TID 0000.0001) write list of available Diagnostics to file: available_diagnostics.log
1471 (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 154 SIuice
1472 (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 155 SIvice
1473 (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 148 SIheff
1474 (PID.TID 0000.0001) SETDIAG: Allocate 1 x 1 Levels for Diagnostic # 145 SIarea
1475 (PID.TID 0000.0001) space allocated for all diagnostics: 4 levels
1476 (PID.TID 0000.0001) set mate pointer for diag # 154 SIuice , Parms: UU M1 , mate: 155
1477 (PID.TID 0000.0001) set mate pointer for diag # 155 SIvice , Parms: VV M1 , mate: 154
1478 (PID.TID 0000.0001) DIAGNOSTICS_SET_POINTERS: Set levels for Outp.Stream: snapshot
1479 (PID.TID 0000.0001) Levels: 1.
1480 (PID.TID 0000.0001) DIAGNOSTICS_SET_POINTERS: done
1481 (PID.TID 0000.0001) ------------------------------------------------------------
1482 (PID.TID 0000.0001) DIAGSTATS_SET_REGIONS: define no region
1483 (PID.TID 0000.0001) ------------------------------------------------------------
1484 (PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 145 SIarea
1485 (PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 148 SIheff
1486 (PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 150 SIhsnow
1487 (PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 154 SIuice
1488 (PID.TID 0000.0001) SETDIAG: Allocate 1 Levels for Stats-Diag # 155 SIvice
1489 (PID.TID 0000.0001) space allocated for all stats-diags: 5 levels
1490 (PID.TID 0000.0001) DIAGSTATS_SET_POINTERS: done
1491 (PID.TID 0000.0001) ------------------------------------------------------------
1492 (PID.TID 0000.0001) DIAGSTATS_INI_IO: open file: iceStDiag.0000000000.txt , unit= 9
1493 (PID.TID 0000.0001) %MON fCori_max = 0.0000000000000E+00
1494 (PID.TID 0000.0001) %MON fCori_min = 0.0000000000000E+00
1495 (PID.TID 0000.0001) %MON fCori_mean = 0.0000000000000E+00
1496 (PID.TID 0000.0001) %MON fCori_sd = 0.0000000000000E+00
1497 (PID.TID 0000.0001) %MON fCoriG_max = 0.0000000000000E+00
1498 (PID.TID 0000.0001) %MON fCoriG_min = 0.0000000000000E+00
1499 (PID.TID 0000.0001) %MON fCoriG_mean = 0.0000000000000E+00
1500 (PID.TID 0000.0001) %MON fCoriG_sd = 0.0000000000000E+00
1501 (PID.TID 0000.0001) %MON fCoriCos_max = 0.0000000000000E+00
1502 (PID.TID 0000.0001) %MON fCoriCos_min = 0.0000000000000E+00
1503 (PID.TID 0000.0001) %MON fCoriCos_mean = 0.0000000000000E+00
1504 (PID.TID 0000.0001) %MON fCoriCos_sd = 0.0000000000000E+00
1505 (PID.TID 0000.0001) INI_CG2D: CG2D normalisation factor = 1.0000000000000001E-01
1506 (PID.TID 0000.0001)
1507 (PID.TID 0000.0001) // =======================================================
1508 (PID.TID 0000.0001) // Model configuration
1509 (PID.TID 0000.0001) // =======================================================
1510 (PID.TID 0000.0001) //
1511 (PID.TID 0000.0001) // "Physical" paramters ( PARM01 in namelist )
1512 (PID.TID 0000.0001) //
1513 (PID.TID 0000.0001) buoyancyRelation = /* Type of relation to get Buoyancy */
1514 (PID.TID 0000.0001) 'OCEANIC'
1515 (PID.TID 0000.0001) ;
1516 (PID.TID 0000.0001) fluidIsAir = /* fluid major constituent is Air */
1517 (PID.TID 0000.0001) F
1518 (PID.TID 0000.0001) ;
1519 (PID.TID 0000.0001) fluidIsWater = /* fluid major constituent is Water */
1520 (PID.TID 0000.0001) T
1521 (PID.TID 0000.0001) ;
1522 (PID.TID 0000.0001) usingPCoords = /* use p (or p*) vertical coordinate */
1523 (PID.TID 0000.0001) F
1524 (PID.TID 0000.0001) ;
1525 (PID.TID 0000.0001) usingZCoords = /* use z (or z*) vertical coordinate */
1526 (PID.TID 0000.0001) T
1527 (PID.TID 0000.0001) ;
1528 (PID.TID 0000.0001) tRef = /* Reference temperature profile ( oC or K ) */
1529 (PID.TID 0000.0001) -1.620000000000000E+00 /* K = 1 */
1530 (PID.TID 0000.0001) ;
1531 (PID.TID 0000.0001) sRef = /* Reference salinity profile ( psu ) */
1532 (PID.TID 0000.0001) 3.000000000000000E+01 /* K = 1 */
1533 (PID.TID 0000.0001) ;
1534 (PID.TID 0000.0001) useStrainTensionVisc= /* Use StrainTension Form of Viscous Operator */
1535 (PID.TID 0000.0001) F
1536 (PID.TID 0000.0001) ;
1537 (PID.TID 0000.0001) useVariableVisc = /* Use variable horizontal viscosity */
1538 (PID.TID 0000.0001) F
1539 (PID.TID 0000.0001) ;
1540 (PID.TID 0000.0001) useHarmonicVisc = /* Use harmonic horizontal viscosity */
1541 (PID.TID 0000.0001) F
1542 (PID.TID 0000.0001) ;
1543 (PID.TID 0000.0001) useBiharmonicVisc= /* Use biharmonic horiz. viscosity */
1544 (PID.TID 0000.0001) F
1545 (PID.TID 0000.0001) ;
1546 (PID.TID 0000.0001) useSmag3D = /* Use isotropic 3-D Smagorinsky viscosity */
1547 (PID.TID 0000.0001) F
1548 (PID.TID 0000.0001) ;
1549 (PID.TID 0000.0001) viscAh = /* Lateral harmonic viscosity ( m^2/s ) */
1550 (PID.TID 0000.0001) 3.000000000000000E+02
1551 (PID.TID 0000.0001) ;
1552 (PID.TID 0000.0001) viscA4 = /* Lateral biharmonic viscosity ( m^4/s ) */
1553 (PID.TID 0000.0001) 0.000000000000000E+00
1554 (PID.TID 0000.0001) ;
1555 (PID.TID 0000.0001) no_slip_sides = /* Viscous BCs: No-slip sides */
1556 (PID.TID 0000.0001) F
1557 (PID.TID 0000.0001) ;
1558 (PID.TID 0000.0001) sideDragFactor = /* side-drag scaling factor (non-dim) */
1559 (PID.TID 0000.0001) 2.000000000000000E+00
1560 (PID.TID 0000.0001) ;
1561 (PID.TID 0000.0001) viscArNr = /* vertical profile of vertical viscosity ( m^2/s )*/
1562 (PID.TID 0000.0001) 3.000000000000000E-02 /* K = 1 */
1563 (PID.TID 0000.0001) ;
1564 (PID.TID 0000.0001) no_slip_bottom = /* Viscous BCs: No-slip bottom */
1565 (PID.TID 0000.0001) T
1566 (PID.TID 0000.0001) ;
1567 (PID.TID 0000.0001) bottomVisc_pCell = /* Partial-cell in bottom Visc. BC */
1568 (PID.TID 0000.0001) F
1569 (PID.TID 0000.0001) ;
1570 (PID.TID 0000.0001) bottomDragLinear = /* linear bottom-drag coefficient ( m/s ) */
1571 (PID.TID 0000.0001) 0.000000000000000E+00
1572 (PID.TID 0000.0001) ;
1573 (PID.TID 0000.0001) bottomDragQuadratic = /* quadratic bottom-drag coefficient (-) */
1574 (PID.TID 0000.0001) 5.000000000000000E-03
1575 (PID.TID 0000.0001) ;
1576 (PID.TID 0000.0001) selectBotDragQuadr = /* select quadratic bottom drag options */
1577 (PID.TID 0000.0001) -1
1578 (PID.TID 0000.0001) ;
1579 (PID.TID 0000.0001) diffKhT = /* Laplacian diffusion of heat laterally ( m^2/s ) */
1580 (PID.TID 0000.0001) 0.000000000000000E+00
1581 (PID.TID 0000.0001) ;
1582 (PID.TID 0000.0001) diffK4T = /* Biharmonic diffusion of heat laterally ( m^4/s ) */
1583 (PID.TID 0000.0001) 0.000000000000000E+00
1584 (PID.TID 0000.0001) ;
1585 (PID.TID 0000.0001) diffKhS = /* Laplacian diffusion of salt laterally ( m^2/s ) */
1586 (PID.TID 0000.0001) 0.000000000000000E+00
1587 (PID.TID 0000.0001) ;
1588 (PID.TID 0000.0001) diffK4S = /* Biharmonic diffusion of salt laterally ( m^4/s ) */
1589 (PID.TID 0000.0001) 0.000000000000000E+00
1590 (PID.TID 0000.0001) ;
1591 (PID.TID 0000.0001) diffKrNrT = /* vertical profile of vertical diffusion of Temp ( m^2/s )*/
1592 (PID.TID 0000.0001) 0.000000000000000E+00 /* K = 1 */
1593 (PID.TID 0000.0001) ;
1594 (PID.TID 0000.0001) diffKrNrS = /* vertical profile of vertical diffusion of Salt ( m^2/s )*/
1595 (PID.TID 0000.0001) 0.000000000000000E+00 /* K = 1 */
1596 (PID.TID 0000.0001) ;
1597 (PID.TID 0000.0001) diffKrBL79surf = /* Surface diffusion for Bryan and Lewis 79 ( m^2/s ) */
1598 (PID.TID 0000.0001) 0.000000000000000E+00
1599 (PID.TID 0000.0001) ;
1600 (PID.TID 0000.0001) diffKrBL79deep = /* Deep diffusion for Bryan and Lewis 1979 ( m^2/s ) */
1601 (PID.TID 0000.0001) 0.000000000000000E+00
1602 (PID.TID 0000.0001) ;
1603 (PID.TID 0000.0001) diffKrBL79scl = /* Depth scale for Bryan and Lewis 1979 ( m ) */
1604 (PID.TID 0000.0001) 2.000000000000000E+02
1605 (PID.TID 0000.0001) ;
1606 (PID.TID 0000.0001) diffKrBL79Ho = /* Turning depth for Bryan and Lewis 1979 ( m ) */
1607 (PID.TID 0000.0001) -2.000000000000000E+03
1608 (PID.TID 0000.0001) ;
1609 (PID.TID 0000.0001) ivdc_kappa = /* Implicit Vertical Diffusivity for Convection ( m^2/s) */
1610 (PID.TID 0000.0001) 0.000000000000000E+00
1611 (PID.TID 0000.0001) ;
1612 (PID.TID 0000.0001) hMixCriteria= /* Criteria for mixed-layer diagnostic */
1613 (PID.TID 0000.0001) -8.000000000000000E-01
1614 (PID.TID 0000.0001) ;
1615 (PID.TID 0000.0001) dRhoSmall = /* Parameter for mixed-layer diagnostic */
1616 (PID.TID 0000.0001) 1.000000000000000E-06
1617 (PID.TID 0000.0001) ;
1618 (PID.TID 0000.0001) hMixSmooth= /* Smoothing parameter for mixed-layer diagnostic */
1619 (PID.TID 0000.0001) 0.000000000000000E+00
1620 (PID.TID 0000.0001) ;
1621 (PID.TID 0000.0001) eosType = /* Type of Equation of State */
1622 (PID.TID 0000.0001) 'LINEAR'
1623 (PID.TID 0000.0001) ;
1624 (PID.TID 0000.0001) tAlpha = /* Linear EOS thermal expansion coefficient ( 1/oC ) */
1625 (PID.TID 0000.0001) 2.000000000000000E-04
1626 (PID.TID 0000.0001) ;
1627 (PID.TID 0000.0001) sBeta = /* Linear EOS haline contraction coefficient ( 1/psu ) */
1628 (PID.TID 0000.0001) 0.000000000000000E+00
1629 (PID.TID 0000.0001) ;
1630 (PID.TID 0000.0001) rhoNil = /* Reference density for Linear EOS ( kg/m^3 ) */
1631 (PID.TID 0000.0001) 1.030000000000000E+03
1632 (PID.TID 0000.0001) ;
1633 (PID.TID 0000.0001) selectP_inEOS_Zc = /* select pressure to use in EOS (0,1,2,3) */
1634 (PID.TID 0000.0001) 0
1635 (PID.TID 0000.0001) 0= -g*rhoConst*z ; 1= pRef (from tRef,sRef); 2= Hyd P ; 3= Hyd+NH P
1636 (PID.TID 0000.0001) ;
1637 (PID.TID 0000.0001) HeatCapacity_Cp = /* Specific heat capacity ( J/kg/K ) */
1638 (PID.TID 0000.0001) 3.986000000000000E+03
1639 (PID.TID 0000.0001) ;
1640 (PID.TID 0000.0001) celsius2K = /* 0 degree Celsius converted to Kelvin ( K ) */
1641 (PID.TID 0000.0001) 2.731500000000000E+02
1642 (PID.TID 0000.0001) ;
1643 (PID.TID 0000.0001) rhoConst = /* Reference density (Boussinesq) ( kg/m^3 ) */
1644 (PID.TID 0000.0001) 1.030000000000000E+03
1645 (PID.TID 0000.0001) ;
1646 (PID.TID 0000.0001) rhoFacC = /* normalized Reference density @ cell-Center (-) */
1647 (PID.TID 0000.0001) 1.000000000000000E+00 /* K = 1 */
1648 (PID.TID 0000.0001) ;
1649 (PID.TID 0000.0001) rhoFacF = /* normalized Reference density @ W-Interface (-) */
1650 (PID.TID 0000.0001) 2 @ 1.000000000000000E+00 /* K = 1: 2 */
1651 (PID.TID 0000.0001) ;
1652 (PID.TID 0000.0001) rhoConstFresh = /* Fresh-water reference density ( kg/m^3 ) */
1653 (PID.TID 0000.0001) 1.000000000000000E+03
1654 (PID.TID 0000.0001) ;
1655 (PID.TID 0000.0001) gravity = /* Gravitational acceleration ( m/s^2 ) */
1656 (PID.TID 0000.0001) 9.810000000000000E+00
1657 (PID.TID 0000.0001) ;
1658 (PID.TID 0000.0001) gBaro = /* Barotropic gravity ( m/s^2 ) */
1659 (PID.TID 0000.0001) 9.810000000000000E+00
1660 (PID.TID 0000.0001) ;
1661 (PID.TID 0000.0001) gravFacC = /* gravity factor (vs surf.) @ cell-Center (-) */
1662 (PID.TID 0000.0001) 1.000000000000000E+00 /* K = 1 */
1663 (PID.TID 0000.0001) ;
1664 (PID.TID 0000.0001) gravFacF = /* gravity factor (vs surf.) @ W-Interface (-) */
1665 (PID.TID 0000.0001) 2 @ 1.000000000000000E+00 /* K = 1: 2 */
1666 (PID.TID 0000.0001) ;
1667 (PID.TID 0000.0001) rotationPeriod = /* Rotation Period ( s ) */
1668 (PID.TID 0000.0001) 8.616400000000000E+04
1669 (PID.TID 0000.0001) ;
1670 (PID.TID 0000.0001) omega = /* Angular velocity ( rad/s ) */
1671 (PID.TID 0000.0001) 7.292123516990375E-05
1672 (PID.TID 0000.0001) ;
1673 (PID.TID 0000.0001) f0 = /* Reference coriolis parameter ( 1/s ) */
1674 (PID.TID 0000.0001) 0.000000000000000E+00
1675 (PID.TID 0000.0001) ;
1676 (PID.TID 0000.0001) beta = /* Beta ( 1/(m.s) ) */
1677 (PID.TID 0000.0001) 0.000000000000000E+00
1678 (PID.TID 0000.0001) ;
1679 (PID.TID 0000.0001) fPrime = /* Second coriolis parameter ( 1/s ) */
1680 (PID.TID 0000.0001) 0.000000000000000E+00
1681 (PID.TID 0000.0001) ;
1682 (PID.TID 0000.0001) rigidLid = /* Rigid lid on/off flag */
1683 (PID.TID 0000.0001) F
1684 (PID.TID 0000.0001) ;
1685 (PID.TID 0000.0001) implicitFreeSurface = /* Implicit free surface on/off flag */
1686 (PID.TID 0000.0001) T
1687 (PID.TID 0000.0001) ;
1688 (PID.TID 0000.0001) freeSurfFac = /* Implicit free surface factor */
1689 (PID.TID 0000.0001) 1.000000000000000E+00
1690 (PID.TID 0000.0001) ;
1691 (PID.TID 0000.0001) implicSurfPress = /* Surface Pressure implicit factor (0-1)*/
1692 (PID.TID 0000.0001) 1.000000000000000E+00
1693 (PID.TID 0000.0001) ;
1694 (PID.TID 0000.0001) implicDiv2Dflow = /* Barot. Flow Div. implicit factor (0-1)*/
1695 (PID.TID 0000.0001) 1.000000000000000E+00
1696 (PID.TID 0000.0001) ;
1697 (PID.TID 0000.0001) uniformLin_PhiSurf = /* use uniform Bo_surf on/off flag*/
1698 (PID.TID 0000.0001) T
1699 (PID.TID 0000.0001) ;
1700 (PID.TID 0000.0001) uniformFreeSurfLev = /* free-surface level-index is uniform */
1701 (PID.TID 0000.0001) T
1702 (PID.TID 0000.0001) ;
1703 (PID.TID 0000.0001) hFacMin = /* minimum partial cell factor (hFac) */
1704 (PID.TID 0000.0001) 1.000000000000000E+00
1705 (PID.TID 0000.0001) ;
1706 (PID.TID 0000.0001) hFacMinDr = /* minimum partial cell thickness ( m) */
1707 (PID.TID 0000.0001) 0.000000000000000E+00
1708 (PID.TID 0000.0001) ;
1709 (PID.TID 0000.0001) exactConserv = /* Exact Volume Conservation on/off flag*/
1710 (PID.TID 0000.0001) F
1711 (PID.TID 0000.0001) ;
1712 (PID.TID 0000.0001) linFSConserveTr = /* Tracer correction for Lin Free Surface on/off flag*/
1713 (PID.TID 0000.0001) F
1714 (PID.TID 0000.0001) ;
1715 (PID.TID 0000.0001) nonlinFreeSurf = /* Non-linear Free Surf. options (-1,0,1,2,3)*/
1716 (PID.TID 0000.0001) 0
1717 (PID.TID 0000.0001) -1,0= Off ; 1,2,3= On, 2=+rescale gU,gV, 3=+update cg2d solv.
1718 (PID.TID 0000.0001) ;
1719 (PID.TID 0000.0001) hFacInf = /* lower threshold for hFac (nonlinFreeSurf only)*/
1720 (PID.TID 0000.0001) 2.000000000000000E-01
1721 (PID.TID 0000.0001) ;
1722 (PID.TID 0000.0001) hFacSup = /* upper threshold for hFac (nonlinFreeSurf only)*/
1723 (PID.TID 0000.0001) 2.000000000000000E+00
1724 (PID.TID 0000.0001) ;
1725 (PID.TID 0000.0001) select_rStar = /* r* Vertical coord. options (=0 r coord.; >0 uses r*)*/
1726 (PID.TID 0000.0001) 0
1727 (PID.TID 0000.0001) ;
1728 (PID.TID 0000.0001) useRealFreshWaterFlux = /* Real Fresh Water Flux on/off flag*/
1729 (PID.TID 0000.0001) F
1730 (PID.TID 0000.0001) ;
1731 (PID.TID 0000.0001) temp_EvPrRn = /* Temp. of Evap/Prec/R (UNSET=use local T)(oC)*/
1732 (PID.TID 0000.0001) 1.234567000000000E+05
1733 (PID.TID 0000.0001) ;
1734 (PID.TID 0000.0001) salt_EvPrRn = /* Salin. of Evap/Prec/R (UNSET=use local S)(psu)*/
1735 (PID.TID 0000.0001) 0.000000000000000E+00
1736 (PID.TID 0000.0001) ;
1737 (PID.TID 0000.0001) selectAddFluid = /* option for mass source/sink of fluid (=0: off) */
1738 (PID.TID 0000.0001) 0
1739 (PID.TID 0000.0001) ;
1740 (PID.TID 0000.0001) temp_addMass = /* Temp. of addMass array (UNSET=use local T)(oC)*/
1741 (PID.TID 0000.0001) 1.234567000000000E+05
1742 (PID.TID 0000.0001) ;
1743 (PID.TID 0000.0001) salt_addMass = /* Salin. of addMass array (UNSET=use local S)(psu)*/
1744 (PID.TID 0000.0001) 0.000000000000000E+00
1745 (PID.TID 0000.0001) ;
1746 (PID.TID 0000.0001) convertFW2Salt = /* convert F.W. Flux to Salt Flux (-1=use local S)(psu)*/
1747 (PID.TID 0000.0001) -1.000000000000000E+00
1748 (PID.TID 0000.0001) ;
1749 (PID.TID 0000.0001) use3Dsolver = /* use 3-D pressure solver on/off flag */
1750 (PID.TID 0000.0001) F
1751 (PID.TID 0000.0001) ;
1752 (PID.TID 0000.0001) nonHydrostatic = /* Non-Hydrostatic on/off flag */
1753 (PID.TID 0000.0001) F
1754 (PID.TID 0000.0001) ;
1755 (PID.TID 0000.0001) nh_Am2 = /* Non-Hydrostatic terms scaling factor */
1756 (PID.TID 0000.0001) 1.000000000000000E+00
1757 (PID.TID 0000.0001) ;
1758 (PID.TID 0000.0001) implicitNHPress = /* Non-Hyd Pressure implicit factor (0-1)*/
1759 (PID.TID 0000.0001) 1.000000000000000E+00
1760 (PID.TID 0000.0001) ;
1761 (PID.TID 0000.0001) selectNHfreeSurf = /* Non-Hyd (free-)Surface option */
1762 (PID.TID 0000.0001) 0
1763 (PID.TID 0000.0001) ;
1764 (PID.TID 0000.0001) quasiHydrostatic = /* Quasi-Hydrostatic on/off flag */
1765 (PID.TID 0000.0001) F
1766 (PID.TID 0000.0001) ;
1767 (PID.TID 0000.0001) calc_wVelocity = /* vertical velocity calculation on/off flag */
1768 (PID.TID 0000.0001) F
1769 (PID.TID 0000.0001) ;
1770 (PID.TID 0000.0001) momStepping = /* Momentum equation on/off flag */
1771 (PID.TID 0000.0001) F
1772 (PID.TID 0000.0001) ;
1773 (PID.TID 0000.0001) vectorInvariantMomentum= /* Vector-Invariant Momentum on/off */
1774 (PID.TID 0000.0001) F
1775 (PID.TID 0000.0001) ;
1776 (PID.TID 0000.0001) momAdvection = /* Momentum advection on/off flag */
1777 (PID.TID 0000.0001) F
1778 (PID.TID 0000.0001) ;
1779 (PID.TID 0000.0001) momViscosity = /* Momentum viscosity on/off flag */
1780 (PID.TID 0000.0001) F
1781 (PID.TID 0000.0001) ;
1782 (PID.TID 0000.0001) momImplVertAdv= /* Momentum implicit vert. advection on/off*/
1783 (PID.TID 0000.0001) F
1784 (PID.TID 0000.0001) ;
1785 (PID.TID 0000.0001) implicitViscosity = /* Implicit viscosity on/off flag */
1786 (PID.TID 0000.0001) F
1787 (PID.TID 0000.0001) ;
1788 (PID.TID 0000.0001) implBottomFriction= /* Implicit bottom friction on/off flag */
1789 (PID.TID 0000.0001) F
1790 (PID.TID 0000.0001) ;
1791 (PID.TID 0000.0001) metricTerms = /* metric-Terms on/off flag */
1792 (PID.TID 0000.0001) F
1793 (PID.TID 0000.0001) ;
1794 (PID.TID 0000.0001) useNHMTerms = /* Non-Hydrostatic Metric-Terms on/off */
1795 (PID.TID 0000.0001) F
1796 (PID.TID 0000.0001) ;
1797 (PID.TID 0000.0001) selectCoriMap = /* Coriolis Map options (0,1,2,3)*/
1798 (PID.TID 0000.0001) 1
1799 (PID.TID 0000.0001) 0= f-Plane ; 1= Beta-Plane ; 2= Spherical ; 3= read from file
1800 (PID.TID 0000.0001) ;
1801 (PID.TID 0000.0001) use3dCoriolis = /* 3-D Coriolis on/off flag */
1802 (PID.TID 0000.0001) F
1803 (PID.TID 0000.0001) ;
1804 (PID.TID 0000.0001) useCoriolis = /* Coriolis on/off flag */
1805 (PID.TID 0000.0001) F
1806 (PID.TID 0000.0001) ;
1807 (PID.TID 0000.0001) useCDscheme = /* CD scheme on/off flag */
1808 (PID.TID 0000.0001) F
1809 (PID.TID 0000.0001) ;
1810 (PID.TID 0000.0001) useEnergyConservingCoriolis= /* Flx-Form Coriolis scheme flag */
1811 (PID.TID 0000.0001) F
1812 (PID.TID 0000.0001) ;
1813 (PID.TID 0000.0001) useJamartWetPoints= /* Coriolis WetPoints method flag */
1814 (PID.TID 0000.0001) T
1815 (PID.TID 0000.0001) ;
1816 (PID.TID 0000.0001) useJamartMomAdv= /* V.I Non-linear terms Jamart flag */
1817 (PID.TID 0000.0001) F
1818 (PID.TID 0000.0001) ;
1819 (PID.TID 0000.0001) useAbsVorticity= /* V.I Works with f+zeta in Coriolis */
1820 (PID.TID 0000.0001) F
1821 (PID.TID 0000.0001) ;
1822 (PID.TID 0000.0001) selectVortScheme= /* V.I Scheme selector for Vorticity-Term */
1823 (PID.TID 0000.0001) 123456789
1824 (PID.TID 0000.0001) = 0 : enstrophy (Shallow-Water Eq.) conserving scheme by Sadourny, JAS 75
1825 (PID.TID 0000.0001) = 1 : same as 0 with modified hFac
1826 (PID.TID 0000.0001) = 2 : energy conserving scheme (used by Sadourny in JAS 75 paper)
1827 (PID.TID 0000.0001) = 3 : energy (general) and enstrophy (2D, nonDiv.) conserving scheme
1828 (PID.TID 0000.0001) from Sadourny (Burridge & Haseler, ECMWF Rep.4, 1977)
1829 (PID.TID 0000.0001) ;
1830 (PID.TID 0000.0001) upwindVorticity= /* V.I Upwind bias vorticity flag */
1831 (PID.TID 0000.0001) F
1832 (PID.TID 0000.0001) ;
1833 (PID.TID 0000.0001) highOrderVorticity= /* V.I High order vort. advect. flag */
1834 (PID.TID 0000.0001) F
1835 (PID.TID 0000.0001) ;
1836 (PID.TID 0000.0001) upwindShear= /* V.I Upwind vertical Shear advection flag */
1837 (PID.TID 0000.0001) F
1838 (PID.TID 0000.0001) ;
1839 (PID.TID 0000.0001) selectKEscheme= /* V.I Kinetic Energy scheme selector */
1840 (PID.TID 0000.0001) 0
1841 (PID.TID 0000.0001) ;
1842 (PID.TID 0000.0001) momForcing = /* Momentum forcing on/off flag */
1843 (PID.TID 0000.0001) F
1844 (PID.TID 0000.0001) ;
1845 (PID.TID 0000.0001) momPressureForcing = /* Momentum pressure term on/off flag */
1846 (PID.TID 0000.0001) F
1847 (PID.TID 0000.0001) ;
1848 (PID.TID 0000.0001) implicitIntGravWave= /* Implicit Internal Gravity Wave flag */
1849 (PID.TID 0000.0001) F
1850 (PID.TID 0000.0001) ;
1851 (PID.TID 0000.0001) staggerTimeStep = /* Stagger time stepping on/off flag */
1852 (PID.TID 0000.0001) T
1853 (PID.TID 0000.0001) ;
1854 (PID.TID 0000.0001) doResetHFactors = /* reset thickness factors @ each time-step */
1855 (PID.TID 0000.0001) F
1856 (PID.TID 0000.0001) ;
1857 (PID.TID 0000.0001) multiDimAdvection = /* enable/disable Multi-Dim Advection */
1858 (PID.TID 0000.0001) T
1859 (PID.TID 0000.0001) ;
1860 (PID.TID 0000.0001) useMultiDimAdvec = /* Multi-Dim Advection is/is-not used */
1861 (PID.TID 0000.0001) F
1862 (PID.TID 0000.0001) ;
1863 (PID.TID 0000.0001) implicitDiffusion = /* Implicit Diffusion on/off flag */
1864 (PID.TID 0000.0001) F
1865 (PID.TID 0000.0001) ;
1866 (PID.TID 0000.0001) tempStepping = /* Temperature equation on/off flag */
1867 (PID.TID 0000.0001) T
1868 (PID.TID 0000.0001) ;
1869 (PID.TID 0000.0001) tempAdvection = /* Temperature advection on/off flag */
1870 (PID.TID 0000.0001) F
1871 (PID.TID 0000.0001) ;
1872 (PID.TID 0000.0001) tempImplVertAdv = /* Temp. implicit vert. advection on/off */
1873 (PID.TID 0000.0001) F
1874 (PID.TID 0000.0001) ;
1875 (PID.TID 0000.0001) tempForcing = /* Temperature forcing on/off flag */
1876 (PID.TID 0000.0001) T
1877 (PID.TID 0000.0001) ;
1878 (PID.TID 0000.0001) doThetaClimRelax = /* apply SST relaxation on/off flag */
1879 (PID.TID 0000.0001) T
1880 (PID.TID 0000.0001) ;
1881 (PID.TID 0000.0001) tempIsActiveTr = /* Temp. is a dynamically Active Tracer */
1882 (PID.TID 0000.0001) F
1883 (PID.TID 0000.0001) ;
1884 (PID.TID 0000.0001) saltStepping = /* Salinity equation on/off flag */
1885 (PID.TID 0000.0001) F
1886 (PID.TID 0000.0001) ;
1887 (PID.TID 0000.0001) saltAdvection = /* Salinity advection on/off flag */
1888 (PID.TID 0000.0001) F
1889 (PID.TID 0000.0001) ;
1890 (PID.TID 0000.0001) saltImplVertAdv = /* Sali. implicit vert. advection on/off */
1891 (PID.TID 0000.0001) F
1892 (PID.TID 0000.0001) ;
1893 (PID.TID 0000.0001) saltForcing = /* Salinity forcing on/off flag */
1894 (PID.TID 0000.0001) F
1895 (PID.TID 0000.0001) ;
1896 (PID.TID 0000.0001) doSaltClimRelax = /* apply SSS relaxation on/off flag */
1897 (PID.TID 0000.0001) F
1898 (PID.TID 0000.0001) ;
1899 (PID.TID 0000.0001) saltIsActiveTr = /* Salt is a dynamically Active Tracer */
1900 (PID.TID 0000.0001) F
1901 (PID.TID 0000.0001) ;
1902 (PID.TID 0000.0001) readBinaryPrec = /* Precision used for reading binary files */
1903 (PID.TID 0000.0001) 64
1904 (PID.TID 0000.0001) ;
1905 (PID.TID 0000.0001) writeBinaryPrec = /* Precision used for writing binary files */
1906 (PID.TID 0000.0001) 64
1907 (PID.TID 0000.0001) ;
1908 (PID.TID 0000.0001) globalFiles = /* write "global" (=not per tile) files */
1909 (PID.TID 0000.0001) F
1910 (PID.TID 0000.0001) ;
1911 (PID.TID 0000.0001) useSingleCpuIO = /* only master MPI process does I/O */
1912 (PID.TID 0000.0001) T
1913 (PID.TID 0000.0001) ;
1914 (PID.TID 0000.0001) useSingleCpuInput = /* only master process reads input */
1915 (PID.TID 0000.0001) T
1916 (PID.TID 0000.0001) ;
1917 (PID.TID 0000.0001) /* debLev[*] : level of debug & auxiliary message printing */
1918 (PID.TID 0000.0001) debLevZero = 0 ; /* level of disabled aux. msg printing */
1919 (PID.TID 0000.0001) debLevA = 1 ; /* level of minimum aux. msg printing */
1920 (PID.TID 0000.0001) debLevB = 2 ; /* level of low aux. print (report read-file opening)*/
1921 (PID.TID 0000.0001) debLevC = 3 ; /* level of moderate debug prt (most pkgs debug msg) */
1922 (PID.TID 0000.0001) debLevD = 4 ; /* level of enhanced debug prt (add DEBUG_STATS prt) */
1923 (PID.TID 0000.0001) debLevE = 5 ; /* level of extensive debug printing */
1924 (PID.TID 0000.0001) debugLevel = /* select debug printing level */
1925 (PID.TID 0000.0001) 2
1926 (PID.TID 0000.0001) ;
1927 (PID.TID 0000.0001) //
1928 (PID.TID 0000.0001) // Elliptic solver(s) paramters ( PARM02 in namelist )
1929 (PID.TID 0000.0001) //
1930 (PID.TID 0000.0001) cg2dMaxIters = /* Upper limit on 2d con. grad iterations */
1931 (PID.TID 0000.0001) 500
1932 (PID.TID 0000.0001) ;
1933 (PID.TID 0000.0001) cg2dChkResFreq = /* 2d con. grad convergence test frequency */
1934 (PID.TID 0000.0001) 1
1935 (PID.TID 0000.0001) ;
1936 (PID.TID 0000.0001) cg2dUseMinResSol= /* use cg2d last-iter(=0) / min-resid.(=1) solution */
1937 (PID.TID 0000.0001) 0
1938 (PID.TID 0000.0001) ;
1939 (PID.TID 0000.0001) cg2dTargetResidual = /* 2d con. grad target residual */
1940 (PID.TID 0000.0001) 1.000000000000000E-12
1941 (PID.TID 0000.0001) ;
1942 (PID.TID 0000.0001) cg2dTargetResWunit = /* CG2d target residual [W units] */
1943 (PID.TID 0000.0001) -1.000000000000000E+00
1944 (PID.TID 0000.0001) ;
1945 (PID.TID 0000.0001) cg2dPreCondFreq = /* Freq. for updating cg2d preconditioner */
1946 (PID.TID 0000.0001) 1
1947 (PID.TID 0000.0001) ;
1948 (PID.TID 0000.0001) useSRCGSolver = /* use single reduction CG solver(s) */
1949 (PID.TID 0000.0001) F
1950 (PID.TID 0000.0001) ;
1951 (PID.TID 0000.0001) printResidualFreq = /* Freq. for printing CG residual */
1952 (PID.TID 0000.0001) 0
1953 (PID.TID 0000.0001) ;
1954 (PID.TID 0000.0001) //
1955 (PID.TID 0000.0001) // Time stepping paramters ( PARM03 in namelist )
1956 (PID.TID 0000.0001) //
1957 (PID.TID 0000.0001) deltaTMom = /* Momentum equation timestep ( s ) */
1958 (PID.TID 0000.0001) 1.800000000000000E+03
1959 (PID.TID 0000.0001) ;
1960 (PID.TID 0000.0001) deltaTFreeSurf = /* FreeSurface equation timestep ( s ) */
1961 (PID.TID 0000.0001) 1.800000000000000E+03
1962 (PID.TID 0000.0001) ;
1963 (PID.TID 0000.0001) dTtracerLev = /* Tracer equation timestep ( s ) */
1964 (PID.TID 0000.0001) 1.800000000000000E+03 /* K = 1 */
1965 (PID.TID 0000.0001) ;
1966 (PID.TID 0000.0001) deltaTClock = /* Model clock timestep ( s ) */
1967 (PID.TID 0000.0001) 1.800000000000000E+03
1968 (PID.TID 0000.0001) ;
1969 (PID.TID 0000.0001) cAdjFreq = /* Convective adjustment interval ( s ) */
1970 (PID.TID 0000.0001) 0.000000000000000E+00
1971 (PID.TID 0000.0001) ;
1972 (PID.TID 0000.0001) momForcingOutAB = /* =1: take Momentum Forcing out of Adams-Bash. stepping */
1973 (PID.TID 0000.0001) 1
1974 (PID.TID 0000.0001) ;
1975 (PID.TID 0000.0001) tracForcingOutAB = /* =1: take T,S,pTr Forcing out of Adams-Bash. stepping */
1976 (PID.TID 0000.0001) 1
1977 (PID.TID 0000.0001) ;
1978 (PID.TID 0000.0001) momDissip_In_AB = /* put Dissipation Tendency in Adams-Bash. stepping */
1979 (PID.TID 0000.0001) T
1980 (PID.TID 0000.0001) ;
1981 (PID.TID 0000.0001) doAB_onGtGs = /* apply AB on Tendencies (rather than on T,S)*/
1982 (PID.TID 0000.0001) T
1983 (PID.TID 0000.0001) ;
1984 (PID.TID 0000.0001) abEps = /* Adams-Bashforth-2 stabilizing weight */
1985 (PID.TID 0000.0001) 1.000000000000000E-01
1986 (PID.TID 0000.0001) ;
1987 (PID.TID 0000.0001) applyExchUV_early = /* Apply EXCH to U,V earlier in time-step */
1988 (PID.TID 0000.0001) F
1989 (PID.TID 0000.0001) ;
1990 (PID.TID 0000.0001) pickupStrictlyMatch= /* stop if pickup do not strictly match */
1991 (PID.TID 0000.0001) T
1992 (PID.TID 0000.0001) ;
1993 (PID.TID 0000.0001) nIter0 = /* Run starting timestep number */
1994 (PID.TID 0000.0001) 0
1995 (PID.TID 0000.0001) ;
1996 (PID.TID 0000.0001) nTimeSteps = /* Number of timesteps */
1997 (PID.TID 0000.0001) 12
1998 (PID.TID 0000.0001) ;
1999 (PID.TID 0000.0001) nEndIter = /* Run ending timestep number */
2000 (PID.TID 0000.0001) 12
2001 (PID.TID 0000.0001) ;
2002 (PID.TID 0000.0001) baseTime = /* Model base time ( s ) */
2003 (PID.TID 0000.0001) 0.000000000000000E+00
2004 (PID.TID 0000.0001) ;
2005 (PID.TID 0000.0001) startTime = /* Run start time ( s ) */
2006 (PID.TID 0000.0001) 0.000000000000000E+00
2007 (PID.TID 0000.0001) ;
2008 (PID.TID 0000.0001) endTime = /* Integration ending time ( s ) */
2009 (PID.TID 0000.0001) 2.160000000000000E+04
2010 (PID.TID 0000.0001) ;
2011 (PID.TID 0000.0001) pChkPtFreq = /* Permanent restart/pickup file interval ( s ) */
2012 (PID.TID 0000.0001) 3.600000000000000E+06
2013 (PID.TID 0000.0001) ;
2014 (PID.TID 0000.0001) chkPtFreq = /* Rolling restart/pickup file interval ( s ) */
2015 (PID.TID 0000.0001) 0.000000000000000E+00
2016 (PID.TID 0000.0001) ;
2017 (PID.TID 0000.0001) pickup_write_mdsio = /* Model IO flag. */
2018 (PID.TID 0000.0001) T
2019 (PID.TID 0000.0001) ;
2020 (PID.TID 0000.0001) pickup_read_mdsio = /* Model IO flag. */
2021 (PID.TID 0000.0001) T
2022 (PID.TID 0000.0001) ;
2023 (PID.TID 0000.0001) pickup_write_immed = /* Model IO flag. */
2024 (PID.TID 0000.0001) F
2025 (PID.TID 0000.0001) ;
2026 (PID.TID 0000.0001) writePickupAtEnd = /* Model IO flag. */
2027 (PID.TID 0000.0001) T
2028 (PID.TID 0000.0001) ;
2029 (PID.TID 0000.0001) dumpFreq = /* Model state write out interval ( s ). */
2030 (PID.TID 0000.0001) 8.640000000000000E+05
2031 (PID.TID 0000.0001) ;
2032 (PID.TID 0000.0001) dumpInitAndLast= /* write out Initial & Last iter. model state */
2033 (PID.TID 0000.0001) T
2034 (PID.TID 0000.0001) ;
2035 (PID.TID 0000.0001) snapshot_mdsio = /* Model IO flag. */
2036 (PID.TID 0000.0001) T
2037 (PID.TID 0000.0001) ;
2038 (PID.TID 0000.0001) monitorFreq = /* Monitor output interval ( s ). */
2039 (PID.TID 0000.0001) 2.160000000000000E+04
2040 (PID.TID 0000.0001) ;
2041 (PID.TID 0000.0001) monitorSelect = /* select group of variables to monitor */
2042 (PID.TID 0000.0001) 2
2043 (PID.TID 0000.0001) ;
2044 (PID.TID 0000.0001) monitor_stdio = /* Model IO flag. */
2045 (PID.TID 0000.0001) T
2046 (PID.TID 0000.0001) ;
2047 (PID.TID 0000.0001) externForcingPeriod = /* forcing period (s) */
2048 (PID.TID 0000.0001) 0.000000000000000E+00
2049 (PID.TID 0000.0001) ;
2050 (PID.TID 0000.0001) externForcingCycle = /* period of the cyle (s). */
2051 (PID.TID 0000.0001) 0.000000000000000E+00
2052 (PID.TID 0000.0001) ;
2053 (PID.TID 0000.0001) tauThetaClimRelax = /* relaxation time scale (s) */
2054 (PID.TID 0000.0001) 2.592000000000000E+06
2055 (PID.TID 0000.0001) ;
2056 (PID.TID 0000.0001) tauSaltClimRelax = /* relaxation time scale (s) */
2057 (PID.TID 0000.0001) 0.000000000000000E+00
2058 (PID.TID 0000.0001) ;
2059 (PID.TID 0000.0001) latBandClimRelax = /* max. Lat. where relaxation */
2060 (PID.TID 0000.0001) 6.300000000000000E+05
2061 (PID.TID 0000.0001) ;
2062 (PID.TID 0000.0001) //
2063 (PID.TID 0000.0001) // Gridding paramters ( PARM04 in namelist )
2064 (PID.TID 0000.0001) //
2065 (PID.TID 0000.0001) usingCartesianGrid = /* Cartesian coordinates flag ( True/False ) */
2066 (PID.TID 0000.0001) T
2067 (PID.TID 0000.0001) ;
2068 (PID.TID 0000.0001) usingCylindricalGrid = /* Cylindrical coordinates flag ( True/False ) */
2069 (PID.TID 0000.0001) F
2070 (PID.TID 0000.0001) ;
2071 (PID.TID 0000.0001) usingSphericalPolarGrid = /* Spherical coordinates flag ( True/False ) */
2072 (PID.TID 0000.0001) F
2073 (PID.TID 0000.0001) ;
2074 (PID.TID 0000.0001) usingCurvilinearGrid = /* Curvilinear coordinates flag ( True/False ) */
2075 (PID.TID 0000.0001) F
2076 (PID.TID 0000.0001) ;
2077 (PID.TID 0000.0001) selectSigmaCoord = /* Hybrid-Sigma Vert. Coordinate option */
2078 (PID.TID 0000.0001) 0
2079 (PID.TID 0000.0001) ;
2080 (PID.TID 0000.0001) rSigmaBnd = /* r/sigma transition ( units of r == m ) */
2081 (PID.TID 0000.0001) 1.234567000000000E+05
2082 (PID.TID 0000.0001) ;
2083 (PID.TID 0000.0001) rkSign = /* index orientation relative to vertical coordinate */
2084 (PID.TID 0000.0001) -1.000000000000000E+00
2085 (PID.TID 0000.0001) ;
2086 (PID.TID 0000.0001) gravitySign = /* gravity orientation relative to vertical coordinate */
2087 (PID.TID 0000.0001) -1.000000000000000E+00
2088 (PID.TID 0000.0001) ;
2089 (PID.TID 0000.0001) seaLev_Z = /* reference height of sea-level [m] */
2090 (PID.TID 0000.0001) 0.000000000000000E+00
2091 (PID.TID 0000.0001) ;
2092 (PID.TID 0000.0001) top_Pres = /* reference pressure at the top [Pa] */
2093 (PID.TID 0000.0001) 0.000000000000000E+00
2094 (PID.TID 0000.0001) ;
2095 (PID.TID 0000.0001) mass2rUnit = /* convert mass per unit area [kg/m2] to r-units [m] */
2096 (PID.TID 0000.0001) 9.708737864077669E-04
2097 (PID.TID 0000.0001) ;
2098 (PID.TID 0000.0001) rUnit2mass = /* convert r-units [m] to mass per unit area [kg/m2] */
2099 (PID.TID 0000.0001) 1.030000000000000E+03
2100 (PID.TID 0000.0001) ;
2101 (PID.TID 0000.0001) drC = /* C spacing ( units of r ) */
2102 (PID.TID 0000.0001) 2 @ 5.000000000000000E+00 /* K = 1: 2 */
2103 (PID.TID 0000.0001) ;
2104 (PID.TID 0000.0001) drF = /* W spacing ( units of r ) */
2105 (PID.TID 0000.0001) 1.000000000000000E+01 /* K = 1 */
2106 (PID.TID 0000.0001) ;
2107 (PID.TID 0000.0001) delX = /* U spacing ( m - cartesian, degrees - spherical ) */
2108 (PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */
2109 (PID.TID 0000.0001) ;
2110 (PID.TID 0000.0001) delY = /* V spacing ( m - cartesian, degrees - spherical ) */
2111 (PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */
2112 (PID.TID 0000.0001) ;
2113 (PID.TID 0000.0001) xgOrigin = /* X-axis origin of West edge (cartesian: m, lat-lon: deg) */
2114 (PID.TID 0000.0001) 0.000000000000000E+00
2115 (PID.TID 0000.0001) ;
2116 (PID.TID 0000.0001) ygOrigin = /* Y-axis origin of South edge (cartesian: m, lat-lon: deg) */
2117 (PID.TID 0000.0001) -1.100000000000000E+05
2118 (PID.TID 0000.0001) ;
2119 (PID.TID 0000.0001) rSphere = /* Radius ( ignored - cartesian, m - spherical ) */
2120 (PID.TID 0000.0001) 6.370000000000000E+06
2121 (PID.TID 0000.0001) ;
2122 (PID.TID 0000.0001) deepAtmosphere = /* Deep/Shallow Atmosphere flag (True/False) */
2123 (PID.TID 0000.0001) F
2124 (PID.TID 0000.0001) ;
2125 (PID.TID 0000.0001) xC = /* xC(:,1,:,1) : P-point X coord ( deg. or m if cartesian) */
2126 (PID.TID 0000.0001) 2.500000000000000E+03, /* I = 1 */
2127 (PID.TID 0000.0001) 7.500000000000000E+03, /* I = 2 */
2128 (PID.TID 0000.0001) 1.250000000000000E+04, /* I = 3 */
2129 (PID.TID 0000.0001) . . .
2130 (PID.TID 0000.0001) 8.750000000000000E+04, /* I = 18 */
2131 (PID.TID 0000.0001) 9.250000000000000E+04, /* I = 19 */
2132 (PID.TID 0000.0001) 9.750000000000000E+04, /* I = 20 */
2133 (PID.TID 0000.0001) 1.025000000000000E+05, /* I = 21 */
2134 (PID.TID 0000.0001) 1.075000000000000E+05, /* I = 22 */
2135 (PID.TID 0000.0001) 1.125000000000000E+05, /* I = 23 */
2136 (PID.TID 0000.0001) . . .
2137 (PID.TID 0000.0001) 1.875000000000000E+05, /* I = 38 */
2138 (PID.TID 0000.0001) 1.925000000000000E+05, /* I = 39 */
2139 (PID.TID 0000.0001) 1.975000000000000E+05, /* I = 40 */
2140 (PID.TID 0000.0001) 2.025000000000000E+05, /* I = 41 */
2141 (PID.TID 0000.0001) 2.075000000000000E+05, /* I = 42 */
2142 (PID.TID 0000.0001) 2.125000000000000E+05, /* I = 43 */
2143 (PID.TID 0000.0001) . . .
2144 (PID.TID 0000.0001) 2.875000000000000E+05, /* I = 58 */
2145 (PID.TID 0000.0001) 2.925000000000000E+05, /* I = 59 */
2146 (PID.TID 0000.0001) 2.975000000000000E+05, /* I = 60 */
2147 (PID.TID 0000.0001) 3.025000000000000E+05, /* I = 61 */
2148 (PID.TID 0000.0001) 3.075000000000000E+05, /* I = 62 */
2149 (PID.TID 0000.0001) 3.125000000000000E+05, /* I = 63 */
2150 (PID.TID 0000.0001) . . .
2151 (PID.TID 0000.0001) 3.875000000000000E+05, /* I = 78 */
2152 (PID.TID 0000.0001) 3.925000000000000E+05, /* I = 79 */
2153 (PID.TID 0000.0001) 3.975000000000000E+05 /* I = 80 */
2154 (PID.TID 0000.0001) ;
2155 (PID.TID 0000.0001) yC = /* yC(1,:,1,:) : P-point Y coord ( deg. or m if cartesian) */
2156 (PID.TID 0000.0001) -1.075000000000000E+05, /* J = 1 */
2157 (PID.TID 0000.0001) -1.025000000000000E+05, /* J = 2 */
2158 (PID.TID 0000.0001) -9.750000000000000E+04, /* J = 3 */
2159 (PID.TID 0000.0001) -9.250000000000000E+04, /* J = 4 */
2160 (PID.TID 0000.0001) -8.750000000000000E+04, /* J = 5 */
2161 (PID.TID 0000.0001) -8.250000000000000E+04, /* J = 6 */
2162 (PID.TID 0000.0001) -7.750000000000000E+04, /* J = 7 */
2163 (PID.TID 0000.0001) -7.250000000000000E+04, /* J = 8 */
2164 (PID.TID 0000.0001) -6.750000000000000E+04, /* J = 9 */
2165 (PID.TID 0000.0001) -6.250000000000000E+04, /* J = 10 */
2166 (PID.TID 0000.0001) -5.750000000000000E+04, /* J = 11 */
2167 (PID.TID 0000.0001) -5.250000000000000E+04, /* J = 12 */
2168 (PID.TID 0000.0001) -4.750000000000000E+04, /* J = 13 */
2169 (PID.TID 0000.0001) -4.250000000000000E+04, /* J = 14 */
2170 (PID.TID 0000.0001) -3.750000000000000E+04, /* J = 15 */
2171 (PID.TID 0000.0001) -3.250000000000000E+04, /* J = 16 */
2172 (PID.TID 0000.0001) -2.750000000000000E+04, /* J = 17 */
2173 (PID.TID 0000.0001) -2.250000000000000E+04, /* J = 18 */
2174 (PID.TID 0000.0001) -1.750000000000000E+04, /* J = 19 */
2175 (PID.TID 0000.0001) -1.250000000000000E+04, /* J = 20 */
2176 (PID.TID 0000.0001) -7.500000000000000E+03, /* J = 21 */
2177 (PID.TID 0000.0001) -2.500000000000000E+03, /* J = 22 */
2178 (PID.TID 0000.0001) 2.500000000000000E+03, /* J = 23 */
2179 (PID.TID 0000.0001) 7.500000000000000E+03, /* J = 24 */
2180 (PID.TID 0000.0001) 1.250000000000000E+04, /* J = 25 */
2181 (PID.TID 0000.0001) 1.750000000000000E+04, /* J = 26 */
2182 (PID.TID 0000.0001) 2.250000000000000E+04, /* J = 27 */
2183 (PID.TID 0000.0001) 2.750000000000000E+04, /* J = 28 */
2184 (PID.TID 0000.0001) 3.250000000000000E+04, /* J = 29 */
2185 (PID.TID 0000.0001) 3.750000000000000E+04, /* J = 30 */
2186 (PID.TID 0000.0001) 4.250000000000000E+04, /* J = 31 */
2187 (PID.TID 0000.0001) 4.750000000000000E+04, /* J = 32 */
2188 (PID.TID 0000.0001) 5.250000000000000E+04, /* J = 33 */
2189 (PID.TID 0000.0001) 5.750000000000000E+04, /* J = 34 */
2190 (PID.TID 0000.0001) 6.250000000000000E+04, /* J = 35 */
2191 (PID.TID 0000.0001) 6.750000000000000E+04, /* J = 36 */
2192 (PID.TID 0000.0001) 7.250000000000000E+04, /* J = 37 */
2193 (PID.TID 0000.0001) 7.750000000000000E+04, /* J = 38 */
2194 (PID.TID 0000.0001) 8.250000000000000E+04, /* J = 39 */
2195 (PID.TID 0000.0001) 8.750000000000000E+04, /* J = 40 */
2196 (PID.TID 0000.0001) 9.250000000000000E+04, /* J = 41 */
2197 (PID.TID 0000.0001) 9.750000000000000E+04 /* J = 42 */
2198 (PID.TID 0000.0001) ;
2199 (PID.TID 0000.0001) rcoord = /* P-point R coordinate ( units of r ) */
2200 (PID.TID 0000.0001) -5.000000000000000E+00 /* K = 1 */
2201 (PID.TID 0000.0001) ;
2202 (PID.TID 0000.0001) rF = /* W-Interf. R coordinate ( units of r ) */
2203 (PID.TID 0000.0001) 0.000000000000000E+00, /* K = 1 */
2204 (PID.TID 0000.0001) -1.000000000000000E+01 /* K = 2 */
2205 (PID.TID 0000.0001) ;
2206 (PID.TID 0000.0001) deepFacC = /* deep-model grid factor @ cell-Center (-) */
2207 (PID.TID 0000.0001) 1.000000000000000E+00 /* K = 1 */
2208 (PID.TID 0000.0001) ;
2209 (PID.TID 0000.0001) deepFacF = /* deep-model grid factor @ W-Interface (-) */
2210 (PID.TID 0000.0001) 2 @ 1.000000000000000E+00 /* K = 1: 2 */
2211 (PID.TID 0000.0001) ;
2212 (PID.TID 0000.0001) rVel2wUnit = /* convert units: rVel -> wSpeed (=1 if z-coord)*/
2213 (PID.TID 0000.0001) 2 @ 1.000000000000000E+00 /* K = 1: 2 */
2214 (PID.TID 0000.0001) ;
2215 (PID.TID 0000.0001) wUnit2rVel = /* convert units: wSpeed -> rVel (=1 if z-coord)*/
2216 (PID.TID 0000.0001) 2 @ 1.000000000000000E+00 /* K = 1: 2 */
2217 (PID.TID 0000.0001) ;
2218 (PID.TID 0000.0001) dBdrRef = /* Vertical grad. of reference buoyancy [(m/s/r)^2] */
2219 (PID.TID 0000.0001) 0.000000000000000E+00 /* K = 1 */
2220 (PID.TID 0000.0001) ;
2221 (PID.TID 0000.0001) rotateGrid = /* use rotated grid ( True/False ) */
2222 (PID.TID 0000.0001) F
2223 (PID.TID 0000.0001) ;
2224 (PID.TID 0000.0001) phiEuler = /* Euler angle, rotation about original z-coordinate [rad] */
2225 (PID.TID 0000.0001) 0.000000000000000E+00
2226 (PID.TID 0000.0001) ;
2227 (PID.TID 0000.0001) thetaEuler = /* Euler angle, rotation about new x-coordinate [rad] */
2228 (PID.TID 0000.0001) 0.000000000000000E+00
2229 (PID.TID 0000.0001) ;
2230 (PID.TID 0000.0001) psiEuler = /* Euler angle, rotation about new z-coordinate [rad] */
2231 (PID.TID 0000.0001) 0.000000000000000E+00
2232 (PID.TID 0000.0001) ;
2233 (PID.TID 0000.0001) dxF = /* dxF(:,1,:,1) ( units: m ) */
2234 (PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */
2235 (PID.TID 0000.0001) ;
2236 (PID.TID 0000.0001) dxF = /* dxF(1,:,1,:) ( units: m ) */
2237 (PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */
2238 (PID.TID 0000.0001) ;
2239 (PID.TID 0000.0001) dyF = /* dyF(:,1,:,1) ( units: m ) */
2240 (PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */
2241 (PID.TID 0000.0001) ;
2242 (PID.TID 0000.0001) dyF = /* dyF(1,:,1,:) ( units: m ) */
2243 (PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */
2244 (PID.TID 0000.0001) ;
2245 (PID.TID 0000.0001) dxG = /* dxG(:,1,:,1) ( units: m ) */
2246 (PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */
2247 (PID.TID 0000.0001) ;
2248 (PID.TID 0000.0001) dxG = /* dxG(1,:,1,:) ( units: m ) */
2249 (PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */
2250 (PID.TID 0000.0001) ;
2251 (PID.TID 0000.0001) dyG = /* dyG(:,1,:,1) ( units: m ) */
2252 (PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */
2253 (PID.TID 0000.0001) ;
2254 (PID.TID 0000.0001) dyG = /* dyG(1,:,1,:) ( units: m ) */
2255 (PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */
2256 (PID.TID 0000.0001) ;
2257 (PID.TID 0000.0001) dxC = /* dxC(:,1,:,1) ( units: m ) */
2258 (PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */
2259 (PID.TID 0000.0001) ;
2260 (PID.TID 0000.0001) dxC = /* dxC(1,:,1,:) ( units: m ) */
2261 (PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */
2262 (PID.TID 0000.0001) ;
2263 (PID.TID 0000.0001) dyC = /* dyC(:,1,:,1) ( units: m ) */
2264 (PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */
2265 (PID.TID 0000.0001) ;
2266 (PID.TID 0000.0001) dyC = /* dyC(1,:,1,:) ( units: m ) */
2267 (PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */
2268 (PID.TID 0000.0001) ;
2269 (PID.TID 0000.0001) dxV = /* dxV(:,1,:,1) ( units: m ) */
2270 (PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */
2271 (PID.TID 0000.0001) ;
2272 (PID.TID 0000.0001) dxV = /* dxV(1,:,1,:) ( units: m ) */
2273 (PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */
2274 (PID.TID 0000.0001) ;
2275 (PID.TID 0000.0001) dyU = /* dyU(:,1,:,1) ( units: m ) */
2276 (PID.TID 0000.0001) 80 @ 5.000000000000000E+03 /* I = 1: 80 */
2277 (PID.TID 0000.0001) ;
2278 (PID.TID 0000.0001) dyU = /* dyU(1,:,1,:) ( units: m ) */
2279 (PID.TID 0000.0001) 42 @ 5.000000000000000E+03 /* J = 1: 42 */
2280 (PID.TID 0000.0001) ;
2281 (PID.TID 0000.0001) rA = /* rA (:,1,:,1) ( units: m^2 ) */
2282 (PID.TID 0000.0001) 80 @ 2.500000000000000E+07 /* I = 1: 80 */
2283 (PID.TID 0000.0001) ;
2284 (PID.TID 0000.0001) rA = /* rA (1,:,1,:) ( units: m^2 ) */
2285 (PID.TID 0000.0001) 42 @ 2.500000000000000E+07 /* J = 1: 42 */
2286 (PID.TID 0000.0001) ;
2287 (PID.TID 0000.0001) rAw = /* rAw(:,1,:,1) ( units: m^2 ) */
2288 (PID.TID 0000.0001) 80 @ 2.500000000000000E+07 /* I = 1: 80 */
2289 (PID.TID 0000.0001) ;
2290 (PID.TID 0000.0001) rAw = /* rAw(1,:,1,:) ( units: m^2 ) */
2291 (PID.TID 0000.0001) 42 @ 2.500000000000000E+07 /* J = 1: 42 */
2292 (PID.TID 0000.0001) ;
2293 (PID.TID 0000.0001) rAs = /* rAs(:,1,:,1) ( units: m^2 ) */
2294 (PID.TID 0000.0001) 80 @ 2.500000000000000E+07 /* I = 1: 80 */
2295 (PID.TID 0000.0001) ;
2296 (PID.TID 0000.0001) rAs = /* rAs(1,:,1,:) ( units: m^2 ) */
2297 (PID.TID 0000.0001) 42 @ 2.500000000000000E+07 /* J = 1: 42 */
2298 (PID.TID 0000.0001) ;
2299 (PID.TID 0000.0001) globalArea = /* Integrated horizontal Area (m^2) */
2300 (PID.TID 0000.0001) 6.950000000000000E+10
2301 (PID.TID 0000.0001) ;
2302 (PID.TID 0000.0001) // =======================================================
2303 (PID.TID 0000.0001) // End of Model config. summary
2304 (PID.TID 0000.0001) // =======================================================
2305 (PID.TID 0000.0001)
2306 (PID.TID 0000.0001) == Packages configuration : Check & print summary ==
2307 (PID.TID 0000.0001)
2308 (PID.TID 0000.0001) SEAICE_CHECK: #define ALLOW_SEAICE
2309 (PID.TID 0000.0001) GAD_CHECK: #define ALLOW_GENERIC_ADVDIFF
2310 (PID.TID 0000.0001) // =======================================================
2311 (PID.TID 0000.0001) // Check Model config. (CONFIG_CHECK):
2312 (PID.TID 0000.0001) // CONFIG_CHECK : Normal End
2313 (PID.TID 0000.0001) // =======================================================
2314 (PID.TID 0000.0001)
2315 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: uVel_3c0.bin
2316 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: vVel_3c0.bin
2317 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: eta_3c0.bin
2318 (PID.TID 0000.0001) Start initial hydrostatic pressure computation
2319 (PID.TID 0000.0001) Pressure is predetermined for buoyancyRelation OCEANIC
2320 (PID.TID 0000.0001)
2321 (PID.TID 0000.0001) write diagnostics summary to file ioUnit: 6
2322 Iter.Nb: 0 ; Time(s): 0.0000000000000E+00
2323 ------------------------------------------------------------------------
2324 2D/3D diagnostics: Number of lists: 1
2325 ------------------------------------------------------------------------
2326 listId= 1 ; file name: snapshot
2327 nFlds, nActive, freq & phase , nLev
2328 4 | 4 | -86400.000000 3600.000000 | 1
2329 levels: 1
2330 diag# | name | ipt | iMate | kLev| count | mate.C|
2331 154 |SIuice | 1 | 2 | 1 | 0 | 0 |
2332 155 |SIvice | 2 | 1 | 1 | 0 | 0 |
2333 148 |SIheff | 3 | 0 | 1 | 0 |
2334 145 |SIarea | 4 | 0 | 1 | 0 |
2335 ------------------------------------------------------------------------
2336 Global & Regional Statistics diagnostics: Number of lists: 1
2337 ------------------------------------------------------------------------
2338 listId= 1 ; file name: iceStDiag
2339 nFlds, nActive, freq & phase |
2340 5 | 5 | 7200.000000 1800.000000 |
2341 Regions: 0
2342 diag# | name | ipt | iMate | Volume | mate-Vol. |
2343 145 |SIarea | 1 | 0 | 0.00000E+00 |
2344 148 |SIheff | 2 | 0 | 0.00000E+00 |
2345 150 |SIhsnow | 3 | 0 | 0.00000E+00 |
2346 154 |SIuice | 4 | 0 | 0.00000E+00 |
2347 155 |SIvice | 5 | 0 | 0.00000E+00 |
2348 ------------------------------------------------------------------------
2349 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: windx.bin
2350 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: tair_4x.bin
2351 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: qa70_4x.bin
2352 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: const_00.bin
2353 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: dsw_100.bin
2354 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: dlw_250.bin
2355 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: tocn.bin
2356 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: heff_quartic.bin
2357 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: const100.bin
2358 (PID.TID 0000.0001) MDS_READ_FIELD: opening global file: const_00.bin
2359 (PID.TID 0000.0001) // =======================================================
2360 (PID.TID 0000.0001) // Model current state
2361 (PID.TID 0000.0001) // =======================================================
2362 (PID.TID 0000.0001)
2363 (PID.TID 0000.0001) // =======================================================
2364 (PID.TID 0000.0001) // Begin MONITOR dynamic field statistics
2365 (PID.TID 0000.0001) // =======================================================
2366 (PID.TID 0000.0001) %MON time_tsnumber = 0
2367 (PID.TID 0000.0001) %MON time_secondsf = 0.0000000000000E+00
2368 (PID.TID 0000.0001) %MON dynstat_eta_max = 1.4855271423662E-02
2369 (PID.TID 0000.0001) %MON dynstat_eta_min = -1.5547625271979E-02
2370 (PID.TID 0000.0001) %MON dynstat_eta_mean = -6.8609663050809E-19
2371 (PID.TID 0000.0001) %MON dynstat_eta_sd = 5.6185276903544E-03
2372 (PID.TID 0000.0001) %MON dynstat_eta_del2 = 3.4210904025025E-06
2373 (PID.TID 0000.0001) %MON dynstat_uvel_max = 5.4694595665363E-01
2374 (PID.TID 0000.0001) %MON dynstat_uvel_min = 8.1797628424127E-02
2375 (PID.TID 0000.0001) %MON dynstat_uvel_mean = 3.2603530929361E-01
2376 (PID.TID 0000.0001) %MON dynstat_uvel_sd = 8.4661197148990E-02
2377 (PID.TID 0000.0001) %MON dynstat_uvel_del2 = 1.3392731599312E-04
2378 (PID.TID 0000.0001) %MON dynstat_vvel_max = 2.2780617104059E-01
2379 (PID.TID 0000.0001) %MON dynstat_vvel_min = -1.4793000868950E-01
2380 (PID.TID 0000.0001) %MON dynstat_vvel_mean = -3.2450632095700E-04
2381 (PID.TID 0000.0001) %MON dynstat_vvel_sd = 6.0970835295293E-02
2382 (PID.TID 0000.0001) %MON dynstat_vvel_del2 = 8.1836652323282E-05
2383 (PID.TID 0000.0001) %MON dynstat_wvel_max = 1.6555698845343E-04
2384 (PID.TID 0000.0001) %MON dynstat_wvel_min = -2.4393468746960E-04
2385 (PID.TID 0000.0001) %MON dynstat_wvel_mean = -1.8006686469634E-21
2386 (PID.TID 0000.0001) %MON dynstat_wvel_sd = 1.8006622332191E-05
2387 (PID.TID 0000.0001) %MON dynstat_wvel_del2 = 3.4047422448573E-07
2388 (PID.TID 0000.0001) %MON dynstat_theta_max = -1.6200000000000E+00
2389 (PID.TID 0000.0001) %MON dynstat_theta_min = -1.6200000000000E+00
2390 (PID.TID 0000.0001) %MON dynstat_theta_mean = -1.6200000000000E+00
2391 (PID.TID 0000.0001) %MON dynstat_theta_sd = 0.0000000000000E+00
2392 (PID.TID 0000.0001) %MON dynstat_theta_del2 = 0.0000000000000E+00
2393 (PID.TID 0000.0001) %MON dynstat_salt_max = 3.0000000000000E+01
2394 (PID.TID 0000.0001) %MON dynstat_salt_min = 3.0000000000000E+01
2395 (PID.TID 0000.0001) %MON dynstat_salt_mean = 3.0000000000000E+01
2396 (PID.TID 0000.0001) %MON dynstat_salt_sd = 0.0000000000000E+00
2397 (PID.TID 0000.0001) %MON dynstat_salt_del2 = 0.0000000000000E+00
2398 (PID.TID 0000.0001) %MON trAdv_CFL_u_max = 0.0000000000000E+00
2399 (PID.TID 0000.0001) %MON trAdv_CFL_v_max = 0.0000000000000E+00
2400 (PID.TID 0000.0001) %MON trAdv_CFL_w_max = 0.0000000000000E+00
2401 (PID.TID 0000.0001) %MON advcfl_uvel_max = 1.9690054439531E-01
2402 (PID.TID 0000.0001) %MON advcfl_vvel_max = 8.2010221574612E-02
2403 (PID.TID 0000.0001) %MON advcfl_wvel_max = 8.7816487489057E-02
2404 (PID.TID 0000.0001) %MON advcfl_W_hf_max = 0.0000000000000E+00
2405 (PID.TID 0000.0001) %MON pe_b_mean = 1.5484032096270E-05
2406 (PID.TID 0000.0001) %MON ke_max = 1.4564487757410E-01
2407 (PID.TID 0000.0001) %MON ke_mean = 5.8130401708830E-02
2408 (PID.TID 0000.0001) %MON ke_vol = 6.9500000000000E+11
2409 (PID.TID 0000.0001) %MON vort_r_min = -1.4191202448594E-04
2410 (PID.TID 0000.0001) %MON vort_r_max = 8.9657385579761E-05
2411 (PID.TID 0000.0001) %MON vort_a_mean = -6.5586096803907E-22
2412 (PID.TID 0000.0001) %MON vort_a_sd = 1.5889649807104E-05
2413 (PID.TID 0000.0001) %MON vort_p_mean = -6.8228760045090E-22
2414 (PID.TID 0000.0001) %MON vort_p_sd = 3.0669223294758E-05
2415 (PID.TID 0000.0001) %MON surfExpan_theta_mean = -1.4394880171946E-21
2416 (PID.TID 0000.0001) %MON surfExpan_salt_mean = 1.6750406018264E-20
2417 (PID.TID 0000.0001) // =======================================================
2418 (PID.TID 0000.0001) // End MONITOR dynamic field statistics
2419 (PID.TID 0000.0001) // =======================================================
2420 (PID.TID 0000.0001) // =======================================================
2421 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
2422 (PID.TID 0000.0001) // =======================================================
2423 (PID.TID 0000.0001) %MON seaice_tsnumber = 0
2424 (PID.TID 0000.0001) %MON seaice_time_sec = 0.0000000000000E+00
2425 (PID.TID 0000.0001) %MON seaice_uice_max = 0.0000000000000E+00
2426 (PID.TID 0000.0001) %MON seaice_uice_min = 0.0000000000000E+00
2427 (PID.TID 0000.0001) %MON seaice_uice_mean = 0.0000000000000E+00
2428 (PID.TID 0000.0001) %MON seaice_uice_sd = 0.0000000000000E+00
2429 (PID.TID 0000.0001) %MON seaice_uice_del2 = 0.0000000000000E+00
2430 (PID.TID 0000.0001) %MON seaice_vice_max = 0.0000000000000E+00
2431 (PID.TID 0000.0001) %MON seaice_vice_min = 0.0000000000000E+00
2432 (PID.TID 0000.0001) %MON seaice_vice_mean = 0.0000000000000E+00
2433 (PID.TID 0000.0001) %MON seaice_vice_sd = 0.0000000000000E+00
2434 (PID.TID 0000.0001) %MON seaice_vice_del2 = 0.0000000000000E+00
2435 (PID.TID 0000.0001) %MON seaice_area_max = 1.0000000000000E+00
2436 (PID.TID 0000.0001) %MON seaice_area_min = 1.0000000000000E+00
2437 (PID.TID 0000.0001) %MON seaice_area_mean = 1.0000000000000E+00
2438 (PID.TID 0000.0001) %MON seaice_area_sd = 0.0000000000000E+00
2439 (PID.TID 0000.0001) %MON seaice_area_del2 = 0.0000000000000E+00
2440 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6257965109702E+00
2441 (PID.TID 0000.0001) %MON seaice_heff_min = 1.3015410245731E-05
2442 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9238269172251E+00
2443 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2084104540500E+00
2444 (PID.TID 0000.0001) %MON seaice_heff_del2 = 4.7611843052501E-04
2445 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
2446 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
2447 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
2448 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
2449 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
2450 (PID.TID 0000.0001) // =======================================================
2451 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
2452 (PID.TID 0000.0001) // =======================================================
2453 (PID.TID 0000.0001) // =======================================================
2454 (PID.TID 0000.0001) // Begin MONITOR EXF statistics
2455 (PID.TID 0000.0001) // =======================================================
2456 (PID.TID 0000.0001) %MON exf_tsnumber = 0
2457 (PID.TID 0000.0001) %MON exf_time_sec = 0.0000000000000E+00
2458 (PID.TID 0000.0001) %MON exf_ustress_max = 1.5090582345178E-01
2459 (PID.TID 0000.0001) %MON exf_ustress_min = 1.2184383176727E-01
2460 (PID.TID 0000.0001) %MON exf_ustress_mean = 1.3639677841392E-01
2461 (PID.TID 0000.0001) %MON exf_ustress_sd = 1.0660482943078E-02
2462 (PID.TID 0000.0001) %MON exf_ustress_del2 = 5.0007679327149E-06
2463 (PID.TID 0000.0001) %MON exf_vstress_max = 0.0000000000000E+00
2464 (PID.TID 0000.0001) %MON exf_vstress_min = 0.0000000000000E+00
2465 (PID.TID 0000.0001) %MON exf_vstress_mean = 0.0000000000000E+00
2466 (PID.TID 0000.0001) %MON exf_vstress_sd = 0.0000000000000E+00
2467 (PID.TID 0000.0001) %MON exf_vstress_del2 = 0.0000000000000E+00
2468 (PID.TID 0000.0001) %MON exf_hflux_max = 6.5891206537299E+01
2469 (PID.TID 0000.0001) %MON exf_hflux_min = -8.1404237426772E+01
2470 (PID.TID 0000.0001) %MON exf_hflux_mean = -1.2615253864378E+01
2471 (PID.TID 0000.0001) %MON exf_hflux_sd = 5.2562085706909E+01
2472 (PID.TID 0000.0001) %MON exf_hflux_del2 = 2.4884597814969E-01
2473 (PID.TID 0000.0001) %MON exf_sflux_max = 2.4349220321116E-08
2474 (PID.TID 0000.0001) %MON exf_sflux_min = -2.4559554123212E-09
2475 (PID.TID 0000.0001) %MON exf_sflux_mean = 1.1240274785629E-08
2476 (PID.TID 0000.0001) %MON exf_sflux_sd = 9.7326718386416E-09
2477 (PID.TID 0000.0001) %MON exf_sflux_del2 = 7.9927232086011E-11
2478 (PID.TID 0000.0001) %MON exf_uwind_max = 1.0000000000000E+01
2479 (PID.TID 0000.0001) %MON exf_uwind_min = 1.0000000000000E+01
2480 (PID.TID 0000.0001) %MON exf_uwind_mean = 1.0000000000000E+01
2481 (PID.TID 0000.0001) %MON exf_uwind_sd = 0.0000000000000E+00
2482 (PID.TID 0000.0001) %MON exf_uwind_del2 = 5.9106750809910E-02
2483 (PID.TID 0000.0001) %MON exf_vwind_max = 0.0000000000000E+00
2484 (PID.TID 0000.0001) %MON exf_vwind_min = 0.0000000000000E+00
2485 (PID.TID 0000.0001) %MON exf_vwind_mean = 0.0000000000000E+00
2486 (PID.TID 0000.0001) %MON exf_vwind_sd = 0.0000000000000E+00
2487 (PID.TID 0000.0001) %MON exf_vwind_del2 = 0.0000000000000E+00
2488 (PID.TID 0000.0001) %MON exf_wspeed_max = 1.0000000000000E+01
2489 (PID.TID 0000.0001) %MON exf_wspeed_min = 1.0000000000000E+01
2490 (PID.TID 0000.0001) %MON exf_wspeed_mean = 1.0000000000000E+01
2491 (PID.TID 0000.0001) %MON exf_wspeed_sd = 0.0000000000000E+00
2492 (PID.TID 0000.0001) %MON exf_wspeed_del2 = 5.9106750809910E-02
2493 (PID.TID 0000.0001) %MON exf_atemp_max = 2.7714691614496E+02
2494 (PID.TID 0000.0001) %MON exf_atemp_min = 2.6915308385504E+02
2495 (PID.TID 0000.0001) %MON exf_atemp_mean = 2.7315000000000E+02
2496 (PID.TID 0000.0001) %MON exf_atemp_sd = 2.9037718208063E+00
2497 (PID.TID 0000.0001) %MON exf_atemp_del2 = 1.2859997507300E-02
2498 (PID.TID 0000.0001) %MON exf_aqh_max = 3.7064806789606E-03
2499 (PID.TID 0000.0001) %MON exf_aqh_min = 2.1441807824757E-03
2500 (PID.TID 0000.0001) %MON exf_aqh_mean = 2.8804761552935E-03
2501 (PID.TID 0000.0001) %MON exf_aqh_sd = 5.6734393616353E-04
2502 (PID.TID 0000.0001) %MON exf_aqh_del2 = 1.7078962742152E-05
2503 (PID.TID 0000.0001) %MON exf_lwflux_max = 5.6469966707287E+01
2504 (PID.TID 0000.0001) %MON exf_lwflux_min = 5.6469966707287E+01
2505 (PID.TID 0000.0001) %MON exf_lwflux_mean = 5.6469966707288E+01
2506 (PID.TID 0000.0001) %MON exf_lwflux_sd = 7.6028072726331E-13
2507 (PID.TID 0000.0001) %MON exf_lwflux_del2 = 3.3377562504116E-01
2508 (PID.TID 0000.0001) %MON exf_precip_max = 0.0000000000000E+00
2509 (PID.TID 0000.0001) %MON exf_precip_min = 0.0000000000000E+00
2510 (PID.TID 0000.0001) %MON exf_precip_mean = 0.0000000000000E+00
2511 (PID.TID 0000.0001) %MON exf_precip_sd = 0.0000000000000E+00
2512 (PID.TID 0000.0001) %MON exf_precip_del2 = 0.0000000000000E+00
2513 (PID.TID 0000.0001) %MON exf_swflux_max = -9.0000000000000E+01
2514 (PID.TID 0000.0001) %MON exf_swflux_min = -9.0000000000000E+01
2515 (PID.TID 0000.0001) %MON exf_swflux_mean = -9.0000000000000E+01
2516 (PID.TID 0000.0001) %MON exf_swflux_sd = 0.0000000000000E+00
2517 (PID.TID 0000.0001) %MON exf_swflux_del2 = 5.3196075728919E-01
2518 (PID.TID 0000.0001) %MON exf_evap_max = 2.4349220321116E-08
2519 (PID.TID 0000.0001) %MON exf_evap_min = -2.4559554123212E-09
2520 (PID.TID 0000.0001) %MON exf_evap_mean = 1.1240274785629E-08
2521 (PID.TID 0000.0001) %MON exf_evap_sd = 9.7326718386416E-09
2522 (PID.TID 0000.0001) %MON exf_evap_del2 = 7.9927232086011E-11
2523 (PID.TID 0000.0001) %MON exf_swdown_max = 1.0000000000000E+02
2524 (PID.TID 0000.0001) %MON exf_swdown_min = 1.0000000000000E+02
2525 (PID.TID 0000.0001) %MON exf_swdown_mean = 1.0000000000000E+02
2526 (PID.TID 0000.0001) %MON exf_swdown_sd = 0.0000000000000E+00
2527 (PID.TID 0000.0001) %MON exf_swdown_del2 = 5.9106750809910E-01
2528 (PID.TID 0000.0001) %MON exf_lwdown_max = 2.5000000000000E+02
2529 (PID.TID 0000.0001) %MON exf_lwdown_min = 2.5000000000000E+02
2530 (PID.TID 0000.0001) %MON exf_lwdown_mean = 2.5000000000000E+02
2531 (PID.TID 0000.0001) %MON exf_lwdown_sd = 0.0000000000000E+00
2532 (PID.TID 0000.0001) %MON exf_lwdown_del2 = 1.4776687702478E+00
2533 (PID.TID 0000.0001) %MON exf_climsst_max = -1.1200000000000E+00
2534 (PID.TID 0000.0001) %MON exf_climsst_min = -1.9000000000000E+00
2535 (PID.TID 0000.0001) %MON exf_climsst_mean = -1.4758380996034E+00
2536 (PID.TID 0000.0001) %MON exf_climsst_sd = 2.7690286535789E-01
2537 (PID.TID 0000.0001) %MON exf_climsst_del2 = 1.0615551600389E-04
2538 (PID.TID 0000.0001) // =======================================================
2539 (PID.TID 0000.0001) // End MONITOR EXF statistics
2540 (PID.TID 0000.0001) // =======================================================
2541 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 9.24106196E-01 1.17296801E-01
2542 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 8.85662486E+02 2.08251541E+02
2543 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 6.32371401E-06 1.43573007E+00
2544 SEAICE_LSR (ipass= 1) iters,dV,Resid= 272 9.57417739E-13 6.31107157E-09
2545 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 1.07958570E+00 4.14679524E-01
2546 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 7.79521472E+02 1.26524975E+02
2547 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 8.80342310E-06 1.85071944E+00
2548 SEAICE_LSR (ipass= 2) iters,dV,Resid= 144 8.10294540E-13 2.33810200E-09
2549 (PID.TID 0000.0001) // =======================================================
2550 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
2551 (PID.TID 0000.0001) // =======================================================
2552 (PID.TID 0000.0001) %MON seaice_tsnumber = 1
2553 (PID.TID 0000.0001) %MON seaice_time_sec = 1.8000000000000E+03
2554 (PID.TID 0000.0001) %MON seaice_uice_max = 4.5501172010391E-01
2555 (PID.TID 0000.0001) %MON seaice_uice_min = 1.8320915382542E-02
2556 (PID.TID 0000.0001) %MON seaice_uice_mean = 1.1783918135520E-01
2557 (PID.TID 0000.0001) %MON seaice_uice_sd = 1.5174085220464E-01
2558 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.3648672953237E-04
2559 (PID.TID 0000.0001) %MON seaice_vice_max = 6.5669958021762E-02
2560 (PID.TID 0000.0001) %MON seaice_vice_min = -5.8329612802282E-02
2561 (PID.TID 0000.0001) %MON seaice_vice_mean = -8.6151447920027E-04
2562 (PID.TID 0000.0001) %MON seaice_vice_sd = 1.4520275861260E-02
2563 (PID.TID 0000.0001) %MON seaice_vice_del2 = 2.4610735448366E-05
2564 (PID.TID 0000.0001) %MON seaice_area_max = 9.9999985023495E-01
2565 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
2566 (PID.TID 0000.0001) %MON seaice_area_mean = 9.6524932912375E-01
2567 (PID.TID 0000.0001) %MON seaice_area_sd = 1.6182614455150E-01
2568 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.2065961966255E-03
2569 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6254861823847E+00
2570 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
2571 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9235072729840E+00
2572 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2083682848396E+00
2573 (PID.TID 0000.0001) %MON seaice_heff_del2 = 4.7613380554169E-04
2574 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
2575 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
2576 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
2577 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
2578 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
2579 (PID.TID 0000.0001) // =======================================================
2580 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
2581 (PID.TID 0000.0001) // =======================================================
2582 Compute Stats, Diag. # 145 SIarea vol( 0 ): 6.950E+10 Parms: SM M1
2583 Compute Stats, Diag. # 148 SIheff vol( 0 ): 6.950E+10 Parms: SM M1
2584 Compute Stats, Diag. # 150 SIhsnow vol( 0 ): 6.950E+10 Parms: SM M1
2585 Compute Stats, Diag. # 154 SIuice vol( 0 ): 6.900E+10 Parms: UU M1
2586 Compute Stats, Diag. # 155 SIvice vol( 0 ): 6.750E+10 Parms: VV M1
2587 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 1.24575219E+00 5.65574080E-01
2588 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 6.98968798E+02 1.59233563E+02
2589 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 1.20886598E-05 2.01173847E+00
2590 SEAICE_LSR (ipass= 1) iters,dV,Resid= 96 8.19677659E-13 1.30024085E-10
2591 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 1.22796014E+00 4.91202394E-01
2592 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 6.42332623E+02 1.75612999E+02
2593 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 1.29511562E-05 1.89993829E+00
2594 SEAICE_LSR (ipass= 2) iters,dV,Resid= 96 8.43818071E-13 6.06997883E-12
2595 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 1
2596 (PID.TID 0000.0001) // =======================================================
2597 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
2598 (PID.TID 0000.0001) // =======================================================
2599 (PID.TID 0000.0001) %MON seaice_tsnumber = 2
2600 (PID.TID 0000.0001) %MON seaice_time_sec = 3.6000000000000E+03
2601 (PID.TID 0000.0001) %MON seaice_uice_max = 6.5738545184736E-01
2602 (PID.TID 0000.0001) %MON seaice_uice_min = 4.7655276683295E-02
2603 (PID.TID 0000.0001) %MON seaice_uice_mean = 2.4300349613666E-01
2604 (PID.TID 0000.0001) %MON seaice_uice_sd = 1.8992634701850E-01
2605 (PID.TID 0000.0001) %MON seaice_uice_del2 = 4.4358596016640E-04
2606 (PID.TID 0000.0001) %MON seaice_vice_max = 1.0968690029464E-01
2607 (PID.TID 0000.0001) %MON seaice_vice_min = -1.1684368787448E-01
2608 (PID.TID 0000.0001) %MON seaice_vice_mean = -8.2359995954803E-03
2609 (PID.TID 0000.0001) %MON seaice_vice_sd = 3.5584913789692E-02
2610 (PID.TID 0000.0001) %MON seaice_vice_del2 = 5.5259111065158E-05
2611 (PID.TID 0000.0001) %MON seaice_area_max = 9.9999973409823E-01
2612 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
2613 (PID.TID 0000.0001) %MON seaice_area_mean = 9.5592095131220E-01
2614 (PID.TID 0000.0001) %MON seaice_area_sd = 1.7829650333387E-01
2615 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.2720303759741E-03
2616 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6252332313723E+00
2617 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
2618 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9232275589035E+00
2619 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2082378933471E+00
2620 (PID.TID 0000.0001) %MON seaice_heff_del2 = 4.7953010548024E-04
2621 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
2622 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
2623 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
2624 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
2625 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
2626 (PID.TID 0000.0001) // =======================================================
2627 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
2628 (PID.TID 0000.0001) // =======================================================
2629 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 1.18112490E+00 4.36067762E-01
2630 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 5.14915068E+02 1.78353453E+02
2631 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 1.46513630E-05 1.72670357E+00
2632 SEAICE_LSR (ipass= 1) iters,dV,Resid= 104 7.75352005E-13 6.39181456E-13
2633 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 1.12940782E+00 4.14228430E-01
2634 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 4.94198666E+02 1.81598400E+02
2635 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 1.44197849E-05 1.51485787E+00
2636 SEAICE_LSR (ipass= 2) iters,dV,Resid= 136 7.44349027E-13 1.00710088E-12
2637 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 2
2638 (PID.TID 0000.0001) // =======================================================
2639 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
2640 (PID.TID 0000.0001) // =======================================================
2641 (PID.TID 0000.0001) %MON seaice_tsnumber = 3
2642 (PID.TID 0000.0001) %MON seaice_time_sec = 5.4000000000000E+03
2643 (PID.TID 0000.0001) %MON seaice_uice_max = 6.1531385250657E-01
2644 (PID.TID 0000.0001) %MON seaice_uice_min = 8.2028144595627E-02
2645 (PID.TID 0000.0001) %MON seaice_uice_mean = 3.0077928673361E-01
2646 (PID.TID 0000.0001) %MON seaice_uice_sd = 1.7282187429729E-01
2647 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.6933238011124E-04
2648 (PID.TID 0000.0001) %MON seaice_vice_max = 1.1699495889048E-01
2649 (PID.TID 0000.0001) %MON seaice_vice_min = -1.5426137886543E-01
2650 (PID.TID 0000.0001) %MON seaice_vice_mean = -1.7770078339897E-02
2651 (PID.TID 0000.0001) %MON seaice_vice_sd = 4.7436132705440E-02
2652 (PID.TID 0000.0001) %MON seaice_vice_del2 = 6.3438647961208E-05
2653 (PID.TID 0000.0001) %MON seaice_area_max = 9.9999860558161E-01
2654 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
2655 (PID.TID 0000.0001) %MON seaice_area_mean = 9.4934826974180E-01
2656 (PID.TID 0000.0001) %MON seaice_area_sd = 1.8770710235892E-01
2657 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.3389489709644E-03
2658 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6250359076917E+00
2659 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
2660 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9229869404420E+00
2661 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2078109192560E+00
2662 (PID.TID 0000.0001) %MON seaice_heff_del2 = 4.9820803046719E-04
2663 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
2664 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
2665 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
2666 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
2667 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
2668 (PID.TID 0000.0001) // =======================================================
2669 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
2670 (PID.TID 0000.0001) // =======================================================
2671 Computing Diagnostic # 154 SIuice Counter: 1 Parms: UU M1
2672 Vector Mate for SIuice Diagnostic # 155 SIvice exists
2673 Computing Diagnostic # 155 SIvice Counter: 1 Parms: VV M1
2674 Vector Mate for SIvice Diagnostic # 154 SIuice exists
2675 Computing Diagnostic # 148 SIheff Counter: 1 Parms: SM M1
2676 Computing Diagnostic # 145 SIarea Counter: 1 Parms: SM M1
2677 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 1.06731930E+00 4.01043367E-01
2678 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 4.44095285E+02 1.84282709E+02
2679 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 1.51266169E-05 1.27063009E+00
2680 SEAICE_LSR (ipass= 1) iters,dV,Resid= 288 9.37680489E-13 6.54073366E-12
2681 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 1.01719225E+00 4.01763341E-01
2682 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 4.44089278E+02 1.82525006E+02
2683 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 1.42146860E-05 1.07118516E+00
2684 SEAICE_LSR (ipass= 2) iters,dV,Resid= 332 9.58108592E-13 9.26515158E-12
2685 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 3
2686 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 2 in timestep 3
2687 (PID.TID 0000.0001) // =======================================================
2688 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
2689 (PID.TID 0000.0001) // =======================================================
2690 (PID.TID 0000.0001) %MON seaice_tsnumber = 4
2691 (PID.TID 0000.0001) %MON seaice_time_sec = 7.2000000000000E+03
2692 (PID.TID 0000.0001) %MON seaice_uice_max = 6.7823170463799E-01
2693 (PID.TID 0000.0001) %MON seaice_uice_min = 1.1686696853560E-01
2694 (PID.TID 0000.0001) %MON seaice_uice_mean = 3.3819234814837E-01
2695 (PID.TID 0000.0001) %MON seaice_uice_sd = 1.6308192722723E-01
2696 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.5588554075202E-04
2697 (PID.TID 0000.0001) %MON seaice_vice_max = 1.1575851556318E-01
2698 (PID.TID 0000.0001) %MON seaice_vice_min = -1.7901253481097E-01
2699 (PID.TID 0000.0001) %MON seaice_vice_mean = -2.4980831416111E-02
2700 (PID.TID 0000.0001) %MON seaice_vice_sd = 5.4095082955701E-02
2701 (PID.TID 0000.0001) %MON seaice_vice_del2 = 6.2077615628916E-05
2702 (PID.TID 0000.0001) %MON seaice_area_max = 9.9999618698801E-01
2703 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
2704 (PID.TID 0000.0001) %MON seaice_area_mean = 9.4390187514123E-01
2705 (PID.TID 0000.0001) %MON seaice_area_sd = 1.9451841809443E-01
2706 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.3958733342904E-03
2707 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6248772087685E+00
2708 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
2709 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9227783636900E+00
2710 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2070505356732E+00
2711 (PID.TID 0000.0001) %MON seaice_heff_del2 = 5.3743449596156E-04
2712 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
2713 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
2714 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
2715 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
2716 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
2717 (PID.TID 0000.0001) // =======================================================
2718 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
2719 (PID.TID 0000.0001) // =======================================================
2720 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 9.30565922E-01 3.81663010E-01
2721 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 3.95327049E+02 1.58858520E+02
2722 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 1.43143283E-05 9.20058095E-01
2723 SEAICE_LSR (ipass= 1) iters,dV,Resid= 466 9.77162795E-13 1.67612290E-11
2724 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 8.67937459E-01 3.45982301E-01
2725 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 3.69549715E+02 1.36777310E+02
2726 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 1.37767852E-05 8.08443990E-01
2727 SEAICE_LSR (ipass= 2) iters,dV,Resid= 488 9.58427782E-13 1.84418156E-11
2728 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 4
2729 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 2 in timestep 4
2730 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 5) in timestep 4
2731 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 5) in timestep 4
2732 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 5) in timestep 4
2733 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 5) in timestep 4
2734 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 5) in timestep 4
2735 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 5) in timestep 4
2736 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 5) in timestep 4
2737 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 5) in timestep 4
2738 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 5) in timestep 4
2739 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 5) in timestep 4
2740 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 5) in timestep 4
2741 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 5) in timestep 4
2742 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 6) in timestep 4
2743 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 6) in timestep 4
2744 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 7) in timestep 4
2745 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 7) in timestep 4
2746 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 7) in timestep 4
2747 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 8) in timestep 4
2748 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 8) in timestep 4
2749 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 8) in timestep 4
2750 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 8) in timestep 4
2751 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 8) in timestep 4
2752 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 8) in timestep 4
2753 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 8) in timestep 4
2754 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 9) in timestep 4
2755 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 9) in timestep 4
2756 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 9) in timestep 4
2757 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 9) in timestep 4
2758 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 9) in timestep 4
2759 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 9) in timestep 4
2760 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 9) in timestep 4
2761 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 9) in timestep 4
2762 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 9) in timestep 4
2763 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 9) in timestep 4
2764 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 9) in timestep 4
2765 (PID.TID 0000.0001) // =======================================================
2766 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
2767 (PID.TID 0000.0001) // =======================================================
2768 (PID.TID 0000.0001) %MON seaice_tsnumber = 5
2769 (PID.TID 0000.0001) %MON seaice_time_sec = 9.0000000000000E+03
2770 (PID.TID 0000.0001) %MON seaice_uice_max = 6.8420100115673E-01
2771 (PID.TID 0000.0001) %MON seaice_uice_min = 1.5034743597109E-01
2772 (PID.TID 0000.0001) %MON seaice_uice_mean = 3.6276968026683E-01
2773 (PID.TID 0000.0001) %MON seaice_uice_sd = 1.5074970861256E-01
2774 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.5977928408406E-04
2775 (PID.TID 0000.0001) %MON seaice_vice_max = 1.1639655838579E-01
2776 (PID.TID 0000.0001) %MON seaice_vice_min = -1.8879456840451E-01
2777 (PID.TID 0000.0001) %MON seaice_vice_mean = -2.8653271088082E-02
2778 (PID.TID 0000.0001) %MON seaice_vice_sd = 5.7089022163774E-02
2779 (PID.TID 0000.0001) %MON seaice_vice_del2 = 6.2524138269790E-05
2780 (PID.TID 0000.0001) %MON seaice_area_max = 9.9999606121869E-01
2781 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
2782 (PID.TID 0000.0001) %MON seaice_area_mean = 9.3900970346375E-01
2783 (PID.TID 0000.0001) %MON seaice_area_sd = 2.0070281841584E-01
2784 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.4798110884318E-03
2785 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6247439950128E+00
2786 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
2787 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9225963118004E+00
2788 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2060522572403E+00
2789 (PID.TID 0000.0001) %MON seaice_heff_del2 = 5.9641814855643E-04
2790 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
2791 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
2792 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
2793 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
2794 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
2795 (PID.TID 0000.0001) // =======================================================
2796 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
2797 (PID.TID 0000.0001) // =======================================================
2798 Compute Stats, Diag. # 145 SIarea vol( 0 ): 2.780E+11 Parms: SM M1
2799 Compute Stats, Diag. # 148 SIheff vol( 0 ): 2.780E+11 Parms: SM M1
2800 Compute Stats, Diag. # 150 SIhsnow vol( 0 ): 2.780E+11 Parms: SM M1
2801 Compute Stats, Diag. # 154 SIuice vol( 0 ): 2.760E+11 Parms: UU M1
2802 Compute Stats, Diag. # 155 SIvice vol( 0 ): 2.700E+11 Parms: VV M1
2803 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 7.45091590E-01 3.35291470E-01
2804 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 3.06811178E+02 1.07191932E+02
2805 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 1.47161602E-05 7.45103601E-01
2806 SEAICE_LSR (ipass= 1) iters,dV,Resid= 570 9.54125667E-13 2.46840874E-11
2807 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 6.98098795E-01 2.98015186E-01
2808 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.88782642E+02 9.59597214E+01
2809 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 1.41196470E-05 6.68024527E-01
2810 SEAICE_LSR (ipass= 2) iters,dV,Resid= 594 9.89028304E-13 2.82408047E-11
2811 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 5
2812 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 2 in timestep 5
2813 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 4) in timestep 5
2814 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 4) in timestep 5
2815 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 4) in timestep 5
2816 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 4) in timestep 5
2817 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 4) in timestep 5
2818 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 4) in timestep 5
2819 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 4) in timestep 5
2820 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 4) in timestep 5
2821 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 4) in timestep 5
2822 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 4) in timestep 5
2823 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 4) in timestep 5
2824 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 4) in timestep 5
2825 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 5) in timestep 5
2826 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 6) in timestep 5
2827 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 6) in timestep 5
2828 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 6) in timestep 5
2829 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 6) in timestep 5
2830 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 6) in timestep 5
2831 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 6) in timestep 5
2832 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 6) in timestep 5
2833 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 6) in timestep 5
2834 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 6) in timestep 5
2835 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 6) in timestep 5
2836 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 6) in timestep 5
2837 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 6) in timestep 5
2838 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 6) in timestep 5
2839 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 6) in timestep 5
2840 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 6) in timestep 5
2841 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 6) in timestep 5
2842 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 7) in timestep 5
2843 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 7) in timestep 5
2844 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 7) in timestep 5
2845 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 7) in timestep 5
2846 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 7) in timestep 5
2847 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 7) in timestep 5
2848 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 7) in timestep 5
2849 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 7) in timestep 5
2850 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 7) in timestep 5
2851 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 7) in timestep 5
2852 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 7) in timestep 5
2853 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 7) in timestep 5
2854 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 7) in timestep 5
2855 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 7) in timestep 5
2856 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 7) in timestep 5
2857 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 8) in timestep 5
2858 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 8) in timestep 5
2859 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 8) in timestep 5
2860 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 8) in timestep 5
2861 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 8) in timestep 5
2862 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 8) in timestep 5
2863 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 8) in timestep 5
2864 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 8) in timestep 5
2865 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 8) in timestep 5
2866 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 8) in timestep 5
2867 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 8) in timestep 5
2868 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 8) in timestep 5
2869 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 8) in timestep 5
2870 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 8) in timestep 5
2871 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 9) in timestep 5
2872 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 9) in timestep 5
2873 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 9) in timestep 5
2874 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 9) in timestep 5
2875 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 9) in timestep 5
2876 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 9) in timestep 5
2877 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 9) in timestep 5
2878 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 9) in timestep 5
2879 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 9) in timestep 5
2880 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 9) in timestep 5
2881 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 9) in timestep 5
2882 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 11) in timestep 5
2883 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 11) in timestep 5
2884 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 12) in timestep 5
2885 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 12) in timestep 5
2886 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 12) in timestep 5
2887 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 12) in timestep 5
2888 (PID.TID 0000.0001) // =======================================================
2889 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
2890 (PID.TID 0000.0001) // =======================================================
2891 (PID.TID 0000.0001) %MON seaice_tsnumber = 6
2892 (PID.TID 0000.0001) %MON seaice_time_sec = 1.0800000000000E+04
2893 (PID.TID 0000.0001) %MON seaice_uice_max = 6.8006199803457E-01
2894 (PID.TID 0000.0001) %MON seaice_uice_min = 1.8513653867074E-01
2895 (PID.TID 0000.0001) %MON seaice_uice_mean = 3.8249642631732E-01
2896 (PID.TID 0000.0001) %MON seaice_uice_sd = 1.3762185327400E-01
2897 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.6751680909509E-04
2898 (PID.TID 0000.0001) %MON seaice_vice_max = 1.1707230095253E-01
2899 (PID.TID 0000.0001) %MON seaice_vice_min = -1.8960684604735E-01
2900 (PID.TID 0000.0001) %MON seaice_vice_mean = -3.0127180004765E-02
2901 (PID.TID 0000.0001) %MON seaice_vice_sd = 5.8105176492401E-02
2902 (PID.TID 0000.0001) %MON seaice_vice_del2 = 7.7356159829784E-05
2903 (PID.TID 0000.0001) %MON seaice_area_max = 9.9999516274166E-01
2904 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
2905 (PID.TID 0000.0001) %MON seaice_area_mean = 9.3483552483658E-01
2906 (PID.TID 0000.0001) %MON seaice_area_sd = 2.0511418797442E-01
2907 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.4826573895740E-03
2908 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6245826413930E+00
2909 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
2910 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9224370847005E+00
2911 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2049143336432E+00
2912 (PID.TID 0000.0001) %MON seaice_heff_del2 = 6.6759479918914E-04
2913 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
2914 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
2915 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
2916 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
2917 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
2918 (PID.TID 0000.0001) // =======================================================
2919 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
2920 (PID.TID 0000.0001) // =======================================================
2921 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 6.52994273E-01 2.69804133E-01
2922 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.45986258E+02 8.14558848E+01
2923 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 1.47039805E-05 6.46512752E-01
2924 SEAICE_LSR (ipass= 1) iters,dV,Resid= 678 9.96161487E-13 3.77880944E-11
2925 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 6.42938244E-01 2.27519422E-01
2926 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.40090512E+02 7.68048751E+01
2927 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 1.34928442E-05 5.94829059E-01
2928 SEAICE_LSR (ipass= 2) iters,dV,Resid= 700 9.87446236E-13 4.23846713E-11
2929 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 6
2930 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 2 in timestep 6
2931 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 3) in timestep 6
2932 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 3) in timestep 6
2933 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 3) in timestep 6
2934 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 3) in timestep 6
2935 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 3) in timestep 6
2936 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 3) in timestep 6
2937 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 3) in timestep 6
2938 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 3) in timestep 6
2939 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 3) in timestep 6
2940 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 3) in timestep 6
2941 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 3) in timestep 6
2942 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 3) in timestep 6
2943 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 5) in timestep 6
2944 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 5) in timestep 6
2945 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 5) in timestep 6
2946 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 5) in timestep 6
2947 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 5) in timestep 6
2948 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 5) in timestep 6
2949 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 5) in timestep 6
2950 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 5) in timestep 6
2951 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 6) in timestep 6
2952 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 6) in timestep 6
2953 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 6) in timestep 6
2954 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 6) in timestep 6
2955 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 6) in timestep 6
2956 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 6) in timestep 6
2957 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 6) in timestep 6
2958 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 6) in timestep 6
2959 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 6) in timestep 6
2960 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 6) in timestep 6
2961 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 6) in timestep 6
2962 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 6) in timestep 6
2963 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 6) in timestep 6
2964 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 6) in timestep 6
2965 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 6) in timestep 6
2966 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 6) in timestep 6
2967 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 6) in timestep 6
2968 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 6) in timestep 6
2969 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 6) in timestep 6
2970 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 7) in timestep 6
2971 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 7) in timestep 6
2972 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 7) in timestep 6
2973 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 7) in timestep 6
2974 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 7) in timestep 6
2975 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 7) in timestep 6
2976 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 7) in timestep 6
2977 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 7) in timestep 6
2978 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 7) in timestep 6
2979 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 7) in timestep 6
2980 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 7) in timestep 6
2981 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 7) in timestep 6
2982 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 7) in timestep 6
2983 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 7) in timestep 6
2984 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 7) in timestep 6
2985 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 7) in timestep 6
2986 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 7) in timestep 6
2987 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 7) in timestep 6
2988 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 7) in timestep 6
2989 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 7) in timestep 6
2990 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 7) in timestep 6
2991 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 8) in timestep 6
2992 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 8) in timestep 6
2993 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 8) in timestep 6
2994 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 8) in timestep 6
2995 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 13 8) in timestep 6
2996 1.9794E-05 4.6786E-01 4.6791E-01 2.5223E-05 4.7875E-01 4.4875E-01 4.7215E-01 4.6036E-01
2997 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 8) in timestep 6
2998 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 8) in timestep 6
2999 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 8) in timestep 6
3000 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 8) in timestep 6
3001 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 8) in timestep 6
3002 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 8) in timestep 6
3003 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 8) in timestep 6
3004 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 8) in timestep 6
3005 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 8) in timestep 6
3006 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 8) in timestep 6
3007 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 8) in timestep 6
3008 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 8) in timestep 6
3009 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 8) in timestep 6
3010 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 8) in timestep 6
3011 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 8) in timestep 6
3012 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 9) in timestep 6
3013 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 9) in timestep 6
3014 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 9) in timestep 6
3015 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 9) in timestep 6
3016 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 9) in timestep 6
3017 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 9) in timestep 6
3018 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 9) in timestep 6
3019 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 9) in timestep 6
3020 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 9) in timestep 6
3021 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 9) in timestep 6
3022 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 9) in timestep 6
3023 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 9) in timestep 6
3024 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 9) in timestep 6
3025 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 9) in timestep 6
3026 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 9) in timestep 6
3027 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 9) in timestep 6
3028 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 9) in timestep 6
3029 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 9) in timestep 6
3030 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 12) in timestep 6
3031 (PID.TID 0000.0001) // =======================================================
3032 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
3033 (PID.TID 0000.0001) // =======================================================
3034 (PID.TID 0000.0001) %MON seaice_tsnumber = 7
3035 (PID.TID 0000.0001) %MON seaice_time_sec = 1.2600000000000E+04
3036 (PID.TID 0000.0001) %MON seaice_uice_max = 6.7647792592897E-01
3037 (PID.TID 0000.0001) %MON seaice_uice_min = 2.1924912243455E-01
3038 (PID.TID 0000.0001) %MON seaice_uice_mean = 3.9908917415815E-01
3039 (PID.TID 0000.0001) %MON seaice_uice_sd = 1.2504799299928E-01
3040 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.7416572003942E-04
3041 (PID.TID 0000.0001) %MON seaice_vice_max = 1.1768454550770E-01
3042 (PID.TID 0000.0001) %MON seaice_vice_min = -1.8697965637756E-01
3043 (PID.TID 0000.0001) %MON seaice_vice_mean = -3.0236929820825E-02
3044 (PID.TID 0000.0001) %MON seaice_vice_sd = 5.8110767908526E-02
3045 (PID.TID 0000.0001) %MON seaice_vice_del2 = 9.4547800883334E-05
3046 (PID.TID 0000.0001) %MON seaice_area_max = 9.9999339675307E-01
3047 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
3048 (PID.TID 0000.0001) %MON seaice_area_mean = 9.3108694151116E-01
3049 (PID.TID 0000.0001) %MON seaice_area_sd = 2.0880881668223E-01
3050 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.4888729383884E-03
3051 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6243768951951E+00
3052 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
3053 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9222966998908E+00
3054 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2037187517493E+00
3055 (PID.TID 0000.0001) %MON seaice_heff_del2 = 7.4453142764657E-04
3056 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
3057 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
3058 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
3059 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
3060 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
3061 (PID.TID 0000.0001) // =======================================================
3062 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
3063 (PID.TID 0000.0001) // =======================================================
3064 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 6.47549513E-01 1.96333553E-01
3065 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.20813127E+02 7.18284536E+01
3066 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 1.31980526E-05 6.29943980E-01
3067 SEAICE_LSR (ipass= 1) iters,dV,Resid= 952 9.89652804E-13 5.92592922E-11
3068 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 6.41729906E-01 2.01797699E-01
3069 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.22690524E+02 7.06612830E+01
3070 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 1.18845977E-05 5.83147770E-01
3071 SEAICE_LSR (ipass= 2) iters,dV,Resid= 1000 9.76524417E-13 6.69844450E-11
3072 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 7
3073 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 2 in timestep 7
3074 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 1) in timestep 7
3075 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 1) in timestep 7
3076 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 1) in timestep 7
3077 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 1) in timestep 7
3078 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 1) in timestep 7
3079 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 1) in timestep 7
3080 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 1) in timestep 7
3081 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 33 1) in timestep 7
3082 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 34 1) in timestep 7
3083 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 4) in timestep 7
3084 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 4) in timestep 7
3085 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 4) in timestep 7
3086 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 4) in timestep 7
3087 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 4) in timestep 7
3088 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 4) in timestep 7
3089 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 4) in timestep 7
3090 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 4) in timestep 7
3091 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 4) in timestep 7
3092 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 4) in timestep 7
3093 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 4) in timestep 7
3094 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 4) in timestep 7
3095 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 4) in timestep 7
3096 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 4) in timestep 7
3097 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 4) in timestep 7
3098 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 5) in timestep 7
3099 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 5) in timestep 7
3100 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 5) in timestep 7
3101 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 5) in timestep 7
3102 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 5) in timestep 7
3103 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 5) in timestep 7
3104 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 5) in timestep 7
3105 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 5) in timestep 7
3106 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 5) in timestep 7
3107 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 5) in timestep 7
3108 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 5) in timestep 7
3109 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 5) in timestep 7
3110 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 5) in timestep 7
3111 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 33 5) in timestep 7
3112 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 8 6) in timestep 7
3113 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 6) in timestep 7
3114 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 6) in timestep 7
3115 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 6) in timestep 7
3116 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 6) in timestep 7
3117 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 6) in timestep 7
3118 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 6) in timestep 7
3119 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 6) in timestep 7
3120 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 6) in timestep 7
3121 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 6) in timestep 7
3122 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 6) in timestep 7
3123 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 6) in timestep 7
3124 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 6) in timestep 7
3125 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 6) in timestep 7
3126 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 6) in timestep 7
3127 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 6) in timestep 7
3128 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 6) in timestep 7
3129 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 6) in timestep 7
3130 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 33 6) in timestep 7
3131 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 8 7) in timestep 7
3132 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 7) in timestep 7
3133 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 7) in timestep 7
3134 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 7) in timestep 7
3135 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 7) in timestep 7
3136 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 14 7) in timestep 7
3137 3.2206E-05 4.7748E-01 4.7752E-01 2.4644E-05 4.8025E-01 4.5452E-01 4.7954E-01 4.6036E-01
3138 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 7) in timestep 7
3139 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 7) in timestep 7
3140 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 7) in timestep 7
3141 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 7) in timestep 7
3142 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 7) in timestep 7
3143 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 7) in timestep 7
3144 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 7) in timestep 7
3145 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 7) in timestep 7
3146 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 7) in timestep 7
3147 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 7) in timestep 7
3148 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 7) in timestep 7
3149 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 7) in timestep 7
3150 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 7) in timestep 7
3151 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 7) in timestep 7
3152 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 7) in timestep 7
3153 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 7) in timestep 7
3154 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 7 8) in timestep 7
3155 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 8) in timestep 7
3156 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 8) in timestep 7
3157 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 11 8) in timestep 7
3158 2.5751E-05 4.7524E-01 4.7529E-01 2.3345E-05 4.7862E-01 4.4988E-01 4.7723E-01 4.6036E-01
3159 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 8) in timestep 7
3160 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 8) in timestep 7
3161 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 8) in timestep 7
3162 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 8) in timestep 7
3163 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 8) in timestep 7
3164 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 8) in timestep 7
3165 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 8) in timestep 7
3166 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 8) in timestep 7
3167 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 8) in timestep 7
3168 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 8) in timestep 7
3169 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 8) in timestep 7
3170 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 8) in timestep 7
3171 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 8) in timestep 7
3172 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 8) in timestep 7
3173 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 8) in timestep 7
3174 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 8) in timestep 7
3175 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 27 8) in timestep 7
3176 2.9668E-05 4.7304E-01 4.7307E-01 2.8751E-05 4.8035E-01 4.5432E-01 4.7799E-01 4.6036E-01
3177 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 8) in timestep 7
3178 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 28 8) in timestep 7
3179 2.4824E-05 4.7594E-01 4.7597E-01 2.9062E-05 4.7727E-01 4.5280E-01 4.7684E-01 4.6036E-01
3180 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 8) in timestep 7
3181 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 8) in timestep 7
3182 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 8) in timestep 7
3183 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 33 8) in timestep 7
3184 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 7 9) in timestep 7
3185 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 8 9) in timestep 7
3186 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 9) in timestep 7
3187 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 9) in timestep 7
3188 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 9) in timestep 7
3189 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 12 9) in timestep 7
3190 2.7559E-05 4.7450E-01 4.7454E-01 3.0231E-05 4.8049E-01 4.5445E-01 4.7873E-01 4.6036E-01
3191 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 9) in timestep 7
3192 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 13 9) in timestep 7
3193 2.6577E-05 4.7754E-01 4.7757E-01 3.6061E-05 4.7956E-01 4.5713E-01 4.7924E-01 4.6036E-01
3194 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 9) in timestep 7
3195 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 9) in timestep 7
3196 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 9) in timestep 7
3197 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 9) in timestep 7
3198 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 9) in timestep 7
3199 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 9) in timestep 7
3200 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 9) in timestep 7
3201 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 9) in timestep 7
3202 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 9) in timestep 7
3203 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 9) in timestep 7
3204 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 9) in timestep 7
3205 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 9) in timestep 7
3206 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 25 9) in timestep 7
3207 2.9534E-05 4.7499E-01 4.7501E-01 3.4179E-05 4.8324E-01 4.6002E-01 4.8305E-01 4.6036E-01
3208 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 9) in timestep 7
3209 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 26 9) in timestep 7
3210 2.4890E-05 4.7567E-01 4.7569E-01 3.4946E-05 4.8130E-01 4.5982E-01 4.8111E-01 4.6036E-01
3211 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 9) in timestep 7
3212 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 9) in timestep 7
3213 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 9) in timestep 7
3214 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 9) in timestep 7
3215 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 9) in timestep 7
3216 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 33 9) in timestep 7
3217 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 10) in timestep 7
3218 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 11 10) in timestep 7
3219 2.2290E-05 4.7182E-01 4.7186E-01 2.9130E-05 4.7818E-01 4.5037E-01 4.7522E-01 4.6036E-01
3220 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 10) in timestep 7
3221 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 17 10) in timestep 7
3222 2.6910E-05 4.7290E-01 4.7291E-01 4.4954E-05 4.7294E-01 4.4423E-01 4.7292E-01 4.6036E-01
3223 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 10) in timestep 7
3224 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 18 10) in timestep 7
3225 2.7041E-05 4.7297E-01 4.7299E-01 4.5187E-05 4.7306E-01 4.4421E-01 4.7301E-01 4.6036E-01
3226 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 10) in timestep 7
3227 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 19 10) in timestep 7
3228 2.7015E-05 4.7298E-01 4.7299E-01 4.4920E-05 4.7330E-01 4.4439E-01 4.7312E-01 4.6036E-01
3229 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 10) in timestep 7
3230 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 24 10) in timestep 7
3231 2.4553E-05 4.7279E-01 4.7280E-01 3.6794E-05 4.7533E-01 4.4541E-01 4.7394E-01 4.6036E-01
3232 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 10) in timestep 7
3233 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 25 10) in timestep 7
3234 2.6549E-05 4.7189E-01 4.7191E-01 3.0556E-05 4.8196E-01 4.5226E-01 4.7781E-01 4.6036E-01
3235 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 10) in timestep 7
3236 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 26 10) in timestep 7
3237 2.3018E-05 4.7229E-01 4.7231E-01 3.0854E-05 4.7812E-01 4.4855E-01 4.7522E-01 4.6036E-01
3238 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 11) in timestep 7
3239 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 15 11) in timestep 7
3240 2.9414E-05 4.7196E-01 4.7197E-01 3.0098E-05 4.8444E-01 4.5306E-01 4.7962E-01 4.6036E-01
3241 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 11) in timestep 7
3242 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 11) in timestep 7
3243 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 11) in timestep 7
3244 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 11) in timestep 7
3245 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 11) in timestep 7
3246 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 20 11) in timestep 7
3247 2.8138E-05 4.7228E-01 4.7229E-01 3.1376E-05 4.8284E-01 4.5127E-01 4.7828E-01 4.6036E-01
3248 (PID.TID 0000.0001) // =======================================================
3249 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
3250 (PID.TID 0000.0001) // =======================================================
3251 (PID.TID 0000.0001) %MON seaice_tsnumber = 8
3252 (PID.TID 0000.0001) %MON seaice_time_sec = 1.4400000000000E+04
3253 (PID.TID 0000.0001) %MON seaice_uice_max = 6.7439459229558E-01
3254 (PID.TID 0000.0001) %MON seaice_uice_min = 2.4952657807570E-01
3255 (PID.TID 0000.0001) %MON seaice_uice_mean = 4.1271957722125E-01
3256 (PID.TID 0000.0001) %MON seaice_uice_sd = 1.1438647387117E-01
3257 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.7800629549016E-04
3258 (PID.TID 0000.0001) %MON seaice_vice_max = 1.1829226838691E-01
3259 (PID.TID 0000.0001) %MON seaice_vice_min = -1.8289935175931E-01
3260 (PID.TID 0000.0001) %MON seaice_vice_mean = -2.9577891522346E-02
3261 (PID.TID 0000.0001) %MON seaice_vice_sd = 5.7608959505960E-02
3262 (PID.TID 0000.0001) %MON seaice_vice_del2 = 9.9795784030770E-05
3263 (PID.TID 0000.0001) %MON seaice_area_max = 9.9999100609788E-01
3264 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
3265 (PID.TID 0000.0001) %MON seaice_area_mean = 9.2759194288882E-01
3266 (PID.TID 0000.0001) %MON seaice_area_sd = 2.1235674285611E-01
3267 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.5031158701423E-03
3268 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6242678683743E+00
3269 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
3270 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9221719105387E+00
3271 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2025216914198E+00
3272 (PID.TID 0000.0001) %MON seaice_heff_del2 = 8.1663820353818E-04
3273 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
3274 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
3275 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
3276 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
3277 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
3278 (PID.TID 0000.0001) // =======================================================
3279 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
3280 (PID.TID 0000.0001) // =======================================================
3281 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 6.09136714E-01 2.11027205E-01
3282 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.16746423E+02 6.95977408E+01
3283 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 1.14825411E-05 5.85098773E-01
3284 SEAICE_LSR (ipass= 1) iters,dV,Resid= 1302 9.97910088E-13 1.02684613E-10
3285 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 5.93106012E-01 2.05396688E-01
3286 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.20851265E+02 6.83696000E+01
3287 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 1.03813179E-05 5.30719729E-01
3288 SEAICE_LSR (ipass= 2) iters,dV,Resid= 1396 9.96314142E-13 1.24672026E-10
3289 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 8
3290 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 2 in timestep 8
3291 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 1) in timestep 8
3292 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 1) in timestep 8
3293 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 1) in timestep 8
3294 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 1) in timestep 8
3295 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 1) in timestep 8
3296 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 1) in timestep 8
3297 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 2) in timestep 8
3298 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 2) in timestep 8
3299 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 3) in timestep 8
3300 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 3) in timestep 8
3301 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 3) in timestep 8
3302 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 3) in timestep 8
3303 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 3) in timestep 8
3304 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 3) in timestep 8
3305 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 3) in timestep 8
3306 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 3) in timestep 8
3307 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 3) in timestep 8
3308 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 3) in timestep 8
3309 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 3) in timestep 8
3310 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 3) in timestep 8
3311 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 3) in timestep 8
3312 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 3) in timestep 8
3313 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 3) in timestep 8
3314 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 4) in timestep 8
3315 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 4) in timestep 8
3316 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 4) in timestep 8
3317 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 8 5) in timestep 8
3318 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 5) in timestep 8
3319 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 5) in timestep 8
3320 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 5) in timestep 8
3321 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 5) in timestep 8
3322 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 5) in timestep 8
3323 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 5) in timestep 8
3324 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 5) in timestep 8
3325 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 5) in timestep 8
3326 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 5) in timestep 8
3327 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 5) in timestep 8
3328 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 5) in timestep 8
3329 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 5) in timestep 8
3330 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 5) in timestep 8
3331 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 6) in timestep 8
3332 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 6) in timestep 8
3333 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 6) in timestep 8
3334 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 6) in timestep 8
3335 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 6) in timestep 8
3336 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 6) in timestep 8
3337 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 6) in timestep 8
3338 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 6) in timestep 8
3339 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 6) in timestep 8
3340 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 6) in timestep 8
3341 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 6) in timestep 8
3342 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 6) in timestep 8
3343 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 6) in timestep 8
3344 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 6) in timestep 8
3345 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 6) in timestep 8
3346 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 6) in timestep 8
3347 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 6) in timestep 8
3348 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 6) in timestep 8
3349 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 6) in timestep 8
3350 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 6) in timestep 8
3351 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 7) in timestep 8
3352 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 7) in timestep 8
3353 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 7) in timestep 8
3354 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 7) in timestep 8
3355 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 7) in timestep 8
3356 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 7) in timestep 8
3357 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 7) in timestep 8
3358 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 7) in timestep 8
3359 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 7) in timestep 8
3360 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 7) in timestep 8
3361 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 7) in timestep 8
3362 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 7) in timestep 8
3363 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 7) in timestep 8
3364 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 7) in timestep 8
3365 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 7) in timestep 8
3366 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 7) in timestep 8
3367 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 7) in timestep 8
3368 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 7) in timestep 8
3369 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 7) in timestep 8
3370 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 7) in timestep 8
3371 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 7) in timestep 8
3372 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 7) in timestep 8
3373 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 7) in timestep 8
3374 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 6 8) in timestep 8
3375 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 8) in timestep 8
3376 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 8) in timestep 8
3377 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 8) in timestep 8
3378 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 8) in timestep 8
3379 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 8) in timestep 8
3380 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 8) in timestep 8
3381 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 8) in timestep 8
3382 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 8) in timestep 8
3383 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 8) in timestep 8
3384 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 8) in timestep 8
3385 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 8) in timestep 8
3386 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 8) in timestep 8
3387 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 8) in timestep 8
3388 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 8) in timestep 8
3389 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 8) in timestep 8
3390 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 8) in timestep 8
3391 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 8) in timestep 8
3392 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 8) in timestep 8
3393 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 8) in timestep 8
3394 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 8) in timestep 8
3395 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 8) in timestep 8
3396 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 8) in timestep 8
3397 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 8) in timestep 8
3398 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 9) in timestep 8
3399 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 9 9) in timestep 8
3400 2.5531E-05 4.7566E-01 4.7570E-01 2.2491E-05 4.8165E-01 4.5919E-01 4.8123E-01 4.6036E-01
3401 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 9) in timestep 8
3402 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 9) in timestep 8
3403 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 9) in timestep 8
3404 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 9) in timestep 8
3405 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 9) in timestep 8
3406 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 9) in timestep 8
3407 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 9) in timestep 8
3408 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 9) in timestep 8
3409 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 9) in timestep 8
3410 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 9) in timestep 8
3411 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 9) in timestep 8
3412 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 9) in timestep 8
3413 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 9) in timestep 8
3414 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 9) in timestep 8
3415 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 9) in timestep 8
3416 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 9) in timestep 8
3417 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 9) in timestep 8
3418 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 9) in timestep 8
3419 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 9) in timestep 8
3420 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 9) in timestep 8
3421 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 9) in timestep 8
3422 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 30 9) in timestep 8
3423 2.9148E-05 4.7576E-01 4.7578E-01 2.6062E-05 4.7696E-01 4.4831E-01 4.7643E-01 4.6036E-01
3424 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 9) in timestep 8
3425 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 10) in timestep 8
3426 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 10) in timestep 8
3427 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 10) in timestep 8
3428 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 10) in timestep 8
3429 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 10) in timestep 8
3430 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 10) in timestep 8
3431 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 10) in timestep 8
3432 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 10) in timestep 8
3433 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 10) in timestep 8
3434 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 10) in timestep 8
3435 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 10) in timestep 8
3436 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 10) in timestep 8
3437 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 10) in timestep 8
3438 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 11) in timestep 8
3439 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 12 11) in timestep 8
3440 2.9284E-05 4.7049E-01 4.7051E-01 4.0842E-05 4.7432E-01 4.4846E-01 4.7225E-01 4.6036E-01
3441 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 11) in timestep 8
3442 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 13 11) in timestep 8
3443 3.6190E-05 4.7002E-01 4.7004E-01 3.9273E-05 4.7902E-01 4.5194E-01 4.7484E-01 4.6036E-01
3444 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 11) in timestep 8
3445 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 14 11) in timestep 8
3446 4.2091E-05 4.6978E-01 4.6979E-01 3.7673E-05 4.8284E-01 4.5455E-01 4.7786E-01 4.6036E-01
3447 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 11) in timestep 8
3448 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 11) in timestep 8
3449 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 11) in timestep 8
3450 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 11) in timestep 8
3451 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 11) in timestep 8
3452 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 11) in timestep 8
3453 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 11) in timestep 8
3454 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 22 11) in timestep 8
3455 3.8801E-05 4.7016E-01 4.7016E-01 4.0101E-05 4.8068E-01 4.5311E-01 4.7621E-01 4.6036E-01
3456 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 11) in timestep 8
3457 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 23 11) in timestep 8
3458 3.4040E-05 4.7043E-01 4.7043E-01 4.1635E-05 4.7735E-01 4.5059E-01 4.7395E-01 4.6036E-01
3459 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 11) in timestep 8
3460 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 24 11) in timestep 8
3461 2.9353E-05 4.7080E-01 4.7080E-01 4.2533E-05 4.7416E-01 4.4809E-01 4.7235E-01 4.6036E-01
3462 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 11) in timestep 8
3463 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 25 11) in timestep 8
3464 2.5343E-05 4.7119E-01 4.7119E-01 4.2516E-05 4.7122E-01 4.4552E-01 4.7120E-01 4.6036E-01
3465 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 11) in timestep 8
3466 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 27 11) in timestep 8
3467 2.5550E-05 4.7047E-01 4.7048E-01 3.1729E-05 4.7589E-01 4.4820E-01 4.7293E-01 4.6036E-01
3468 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 12) in timestep 8
3469 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 14 12) in timestep 8
3470 2.5320E-05 4.7129E-01 4.7129E-01 4.1692E-05 4.7194E-01 4.4569E-01 4.7157E-01 4.6036E-01
3471 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 12) in timestep 8
3472 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 15 12) in timestep 8
3473 2.6002E-05 4.7137E-01 4.7137E-01 4.3013E-05 4.7211E-01 4.4587E-01 4.7169E-01 4.6036E-01
3474 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 12) in timestep 8
3475 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 16 12) in timestep 8
3476 2.6992E-05 4.7128E-01 4.7128E-01 4.3350E-05 4.7272E-01 4.4648E-01 4.7191E-01 4.6036E-01
3477 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 12) in timestep 8
3478 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 17 12) in timestep 8
3479 2.7175E-05 4.7128E-01 4.7128E-01 4.3478E-05 4.7284E-01 4.4656E-01 4.7197E-01 4.6036E-01
3480 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 12) in timestep 8
3481 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 18 12) in timestep 8
3482 2.6763E-05 4.7134E-01 4.7134E-01 4.3553E-05 4.7247E-01 4.4619E-01 4.7183E-01 4.6036E-01
3483 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 12) in timestep 8
3484 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 22 12) in timestep 8
3485 2.5954E-05 4.7090E-01 4.7090E-01 3.5558E-05 4.7593E-01 4.4907E-01 4.7333E-01 4.6036E-01
3486 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 12) in timestep 8
3487 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 25 12) in timestep 8
3488 2.0555E-05 4.7116E-01 4.7116E-01 3.0505E-05 4.7321E-01 4.4572E-01 4.7203E-01 4.6036E-01
3489 (PID.TID 0000.0001) // =======================================================
3490 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
3491 (PID.TID 0000.0001) // =======================================================
3492 (PID.TID 0000.0001) %MON seaice_tsnumber = 9
3493 (PID.TID 0000.0001) %MON seaice_time_sec = 1.6200000000000E+04
3494 (PID.TID 0000.0001) %MON seaice_uice_max = 6.7330113993649E-01
3495 (PID.TID 0000.0001) %MON seaice_uice_min = 2.7578879871194E-01
3496 (PID.TID 0000.0001) %MON seaice_uice_mean = 4.2400032890920E-01
3497 (PID.TID 0000.0001) %MON seaice_uice_sd = 1.0562783766309E-01
3498 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.8136434389675E-04
3499 (PID.TID 0000.0001) %MON seaice_vice_max = 1.1901481644885E-01
3500 (PID.TID 0000.0001) %MON seaice_vice_min = -1.7913695067767E-01
3501 (PID.TID 0000.0001) %MON seaice_vice_mean = -2.8547247838628E-02
3502 (PID.TID 0000.0001) %MON seaice_vice_sd = 5.6910024273435E-02
3503 (PID.TID 0000.0001) %MON seaice_vice_del2 = 9.8483202600959E-05
3504 (PID.TID 0000.0001) %MON seaice_area_max = 9.9998862335943E-01
3505 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
3506 (PID.TID 0000.0001) %MON seaice_area_mean = 9.2430856497082E-01
3507 (PID.TID 0000.0001) %MON seaice_area_sd = 2.1588044417322E-01
3508 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.5140237072094E-03
3509 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6241798921269E+00
3510 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
3511 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9220601304366E+00
3512 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2013544930330E+00
3513 (PID.TID 0000.0001) %MON seaice_heff_del2 = 8.8348433710034E-04
3514 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
3515 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
3516 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
3517 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
3518 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
3519 (PID.TID 0000.0001) // =======================================================
3520 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
3521 (PID.TID 0000.0001) // =======================================================
3522 Compute Stats, Diag. # 145 SIarea vol( 0 ): 2.780E+11 Parms: SM M1
3523 Compute Stats, Diag. # 148 SIheff vol( 0 ): 2.780E+11 Parms: SM M1
3524 Compute Stats, Diag. # 150 SIhsnow vol( 0 ): 2.780E+11 Parms: SM M1
3525 Compute Stats, Diag. # 154 SIuice vol( 0 ): 2.760E+11 Parms: UU M1
3526 Compute Stats, Diag. # 155 SIvice vol( 0 ): 2.700E+11 Parms: VV M1
3527 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 5.54926457E-01 1.72691859E-01
3528 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.21168498E+02 6.68872813E+01
3529 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 9.97760509E-06 5.18064758E-01
3530 SEAICE_LSR (ipass= 1) iters,dV,Resid= 1500 1.11697318E-11 1.98288630E-09
3531 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 5.42968453E-01 1.66631934E-01
3532 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.27250679E+02 6.57590632E+01
3533 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 9.04052485E-06 4.74575606E-01
3534 SEAICE_LSR (ipass= 2) iters,dV,Resid= 1500 1.50034221E-11 2.89308719E-09
3535 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 9
3536 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 2 in timestep 9
3537 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 7 1) in timestep 9
3538 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 8 1) in timestep 9
3539 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 2) in timestep 9
3540 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 3) in timestep 9
3541 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 3) in timestep 9
3542 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 3) in timestep 9
3543 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 3) in timestep 9
3544 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 4) in timestep 9
3545 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 4) in timestep 9
3546 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 4) in timestep 9
3547 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 33 4) in timestep 9
3548 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 5) in timestep 9
3549 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 5) in timestep 9
3550 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 5) in timestep 9
3551 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 5) in timestep 9
3552 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 5) in timestep 9
3553 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 5) in timestep 9
3554 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 5) in timestep 9
3555 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 5) in timestep 9
3556 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 5) in timestep 9
3557 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 5) in timestep 9
3558 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 5) in timestep 9
3559 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 5) in timestep 9
3560 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 5) in timestep 9
3561 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 5) in timestep 9
3562 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 6) in timestep 9
3563 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 6) in timestep 9
3564 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 6) in timestep 9
3565 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 6) in timestep 9
3566 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 6) in timestep 9
3567 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 6) in timestep 9
3568 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 6) in timestep 9
3569 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 6) in timestep 9
3570 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 6) in timestep 9
3571 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 6) in timestep 9
3572 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 6) in timestep 9
3573 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 6) in timestep 9
3574 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 6) in timestep 9
3575 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 6) in timestep 9
3576 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 6) in timestep 9
3577 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 6) in timestep 9
3578 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 6) in timestep 9
3579 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 6) in timestep 9
3580 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 7) in timestep 9
3581 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 7) in timestep 9
3582 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 7) in timestep 9
3583 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 7) in timestep 9
3584 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 7) in timestep 9
3585 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 7) in timestep 9
3586 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 7) in timestep 9
3587 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 7) in timestep 9
3588 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 7) in timestep 9
3589 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 7) in timestep 9
3590 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 7) in timestep 9
3591 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 7) in timestep 9
3592 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 7) in timestep 9
3593 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 7) in timestep 9
3594 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 7) in timestep 9
3595 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 7) in timestep 9
3596 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 7) in timestep 9
3597 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 7) in timestep 9
3598 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 7) in timestep 9
3599 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 7) in timestep 9
3600 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 8) in timestep 9
3601 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 8) in timestep 9
3602 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 8) in timestep 9
3603 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 8) in timestep 9
3604 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 8) in timestep 9
3605 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 8) in timestep 9
3606 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 8) in timestep 9
3607 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 8) in timestep 9
3608 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 8) in timestep 9
3609 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 8) in timestep 9
3610 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 8) in timestep 9
3611 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 8) in timestep 9
3612 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 8) in timestep 9
3613 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 8) in timestep 9
3614 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 8) in timestep 9
3615 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 8) in timestep 9
3616 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 8) in timestep 9
3617 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 8) in timestep 9
3618 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 8) in timestep 9
3619 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 8) in timestep 9
3620 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 8) in timestep 9
3621 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 8 9) in timestep 9
3622 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 9) in timestep 9
3623 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 9) in timestep 9
3624 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 9) in timestep 9
3625 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 9) in timestep 9
3626 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 9) in timestep 9
3627 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 9) in timestep 9
3628 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 9) in timestep 9
3629 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 9) in timestep 9
3630 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 9) in timestep 9
3631 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 9) in timestep 9
3632 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 9) in timestep 9
3633 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 9) in timestep 9
3634 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 9) in timestep 9
3635 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 9) in timestep 9
3636 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 9) in timestep 9
3637 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 9) in timestep 9
3638 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 9) in timestep 9
3639 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 9) in timestep 9
3640 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 9) in timestep 9
3641 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 9) in timestep 9
3642 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 9) in timestep 9
3643 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 9) in timestep 9
3644 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 33 9) in timestep 9
3645 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 10) in timestep 9
3646 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 10) in timestep 9
3647 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 10) in timestep 9
3648 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 10) in timestep 9
3649 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 10) in timestep 9
3650 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 10) in timestep 9
3651 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 10) in timestep 9
3652 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 10) in timestep 9
3653 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 11) in timestep 9
3654 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 11) in timestep 9
3655 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 11) in timestep 9
3656 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 11) in timestep 9
3657 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 11) in timestep 9
3658 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 11) in timestep 9
3659 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 11) in timestep 9
3660 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 11) in timestep 9
3661 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 11) in timestep 9
3662 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 11) in timestep 9
3663 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 11) in timestep 9
3664 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 11) in timestep 9
3665 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 11) in timestep 9
3666 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 11) in timestep 9
3667 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 11) in timestep 9
3668 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 12) in timestep 9
3669 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 10 12) in timestep 9
3670 2.3135E-05 4.6971E-01 4.6972E-01 3.9399E-05 4.6994E-01 4.4716E-01 4.6981E-01 4.6036E-01
3671 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 12) in timestep 9
3672 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 12) in timestep 9
3673 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 12) in timestep 9
3674 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 12) in timestep 9
3675 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 12) in timestep 9
3676 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 12) in timestep 9
3677 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 13) in timestep 9
3678 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 14 13) in timestep 9
3679 2.7089E-05 4.6958E-01 4.6958E-01 4.0881E-05 4.7147E-01 4.4793E-01 4.7038E-01 4.6036E-01
3680 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 13) in timestep 9
3681 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 15 13) in timestep 9
3682 2.9187E-05 4.6938E-01 4.6938E-01 4.0637E-05 4.7279E-01 4.4898E-01 4.7088E-01 4.6036E-01
3683 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 13) in timestep 9
3684 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 16 13) in timestep 9
3685 3.0096E-05 4.6928E-01 4.6928E-01 4.0529E-05 4.7335E-01 4.4943E-01 4.7111E-01 4.6036E-01
3686 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 13) in timestep 9
3687 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 17 13) in timestep 9
3688 2.9912E-05 4.6931E-01 4.6931E-01 4.0618E-05 4.7322E-01 4.4939E-01 4.7106E-01 4.6036E-01
3689 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 13) in timestep 9
3690 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 18 13) in timestep 9
3691 2.8908E-05 4.6940E-01 4.6940E-01 4.0833E-05 4.7257E-01 4.4904E-01 4.7081E-01 4.6036E-01
3692 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 13) in timestep 9
3693 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 19 13) in timestep 9
3694 2.7050E-05 4.6954E-01 4.6954E-01 4.1131E-05 4.7148E-01 4.4841E-01 4.7038E-01 4.6036E-01
3695 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 13) in timestep 9
3696 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 20 13) in timestep 9
3697 2.4868E-05 4.6973E-01 4.6973E-01 4.1250E-05 4.6975E-01 4.4686E-01 4.6974E-01 4.6036E-01
3698 (PID.TID 0000.0001) // =======================================================
3699 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
3700 (PID.TID 0000.0001) // =======================================================
3701 (PID.TID 0000.0001) %MON seaice_tsnumber = 10
3702 (PID.TID 0000.0001) %MON seaice_time_sec = 1.8000000000000E+04
3703 (PID.TID 0000.0001) %MON seaice_uice_max = 6.7299217759957E-01
3704 (PID.TID 0000.0001) %MON seaice_uice_min = 2.9846278270342E-01
3705 (PID.TID 0000.0001) %MON seaice_uice_mean = 4.3340885265237E-01
3706 (PID.TID 0000.0001) %MON seaice_uice_sd = 9.8500666707418E-02
3707 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.8543677570022E-04
3708 (PID.TID 0000.0001) %MON seaice_vice_max = 1.1969853117209E-01
3709 (PID.TID 0000.0001) %MON seaice_vice_min = -1.7611370983054E-01
3710 (PID.TID 0000.0001) %MON seaice_vice_mean = -2.7355475114555E-02
3711 (PID.TID 0000.0001) %MON seaice_vice_sd = 5.6176565057410E-02
3712 (PID.TID 0000.0001) %MON seaice_vice_del2 = 9.6259655195997E-05
3713 (PID.TID 0000.0001) %MON seaice_area_max = 9.9998658897306E-01
3714 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
3715 (PID.TID 0000.0001) %MON seaice_area_mean = 9.2132317089598E-01
3716 (PID.TID 0000.0001) %MON seaice_area_sd = 2.1887123036721E-01
3717 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.5095898819718E-03
3718 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6241073903120E+00
3719 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
3720 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9219597283562E+00
3721 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.2002333693714E+00
3722 (PID.TID 0000.0001) %MON seaice_heff_del2 = 9.4827533208204E-04
3723 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
3724 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
3725 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
3726 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
3727 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
3728 (PID.TID 0000.0001) // =======================================================
3729 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
3730 (PID.TID 0000.0001) // =======================================================
3731 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 5.14003468E-01 1.46717073E-01
3732 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.31140554E+02 6.40347154E+01
3733 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 8.62493665E-06 4.67567814E-01
3734 SEAICE_LSR (ipass= 1) iters,dV,Resid= 1500 2.00340189E-10 5.26389789E-08
3735 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 5.04617086E-01 1.43862717E-01
3736 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.37672046E+02 6.28745518E+01
3737 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 7.84928074E-06 4.33878153E-01
3738 SEAICE_LSR (ipass= 2) iters,dV,Resid= 1500 2.55308392E-10 7.51401191E-08
3739 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 10
3740 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 2 in timestep 10
3741 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 21) in timestep 10
3742 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 7 1) in timestep 10
3743 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 1) in timestep 10
3744 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 2) in timestep 10
3745 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 3) in timestep 10
3746 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 3) in timestep 10
3747 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 3) in timestep 10
3748 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 4) in timestep 10
3749 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 4) in timestep 10
3750 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 4) in timestep 10
3751 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 4) in timestep 10
3752 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 4) in timestep 10
3753 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 34 4) in timestep 10
3754 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 5) in timestep 10
3755 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 5) in timestep 10
3756 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 5) in timestep 10
3757 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 5) in timestep 10
3758 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 5) in timestep 10
3759 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 5) in timestep 10
3760 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 5) in timestep 10
3761 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 5) in timestep 10
3762 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 5) in timestep 10
3763 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 5) in timestep 10
3764 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 5) in timestep 10
3765 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 5) in timestep 10
3766 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 5) in timestep 10
3767 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 5) in timestep 10
3768 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 6 6) in timestep 10
3769 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 6) in timestep 10
3770 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 6) in timestep 10
3771 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 6) in timestep 10
3772 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 6) in timestep 10
3773 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 6) in timestep 10
3774 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 6) in timestep 10
3775 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 6) in timestep 10
3776 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 6) in timestep 10
3777 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 6) in timestep 10
3778 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 6) in timestep 10
3779 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 6) in timestep 10
3780 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 6) in timestep 10
3781 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 6) in timestep 10
3782 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 6) in timestep 10
3783 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 6) in timestep 10
3784 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 6) in timestep 10
3785 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 6) in timestep 10
3786 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 6) in timestep 10
3787 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 6) in timestep 10
3788 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 7) in timestep 10
3789 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 7) in timestep 10
3790 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 7) in timestep 10
3791 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 7) in timestep 10
3792 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 7) in timestep 10
3793 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 7) in timestep 10
3794 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 7) in timestep 10
3795 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 7) in timestep 10
3796 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 7) in timestep 10
3797 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 7) in timestep 10
3798 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 7) in timestep 10
3799 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 7) in timestep 10
3800 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 7) in timestep 10
3801 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 7) in timestep 10
3802 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 7) in timestep 10
3803 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 7) in timestep 10
3804 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 7) in timestep 10
3805 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 7) in timestep 10
3806 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 7) in timestep 10
3807 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 7) in timestep 10
3808 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 35 7) in timestep 10
3809 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 8 8) in timestep 10
3810 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 8) in timestep 10
3811 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 8) in timestep 10
3812 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 8) in timestep 10
3813 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 8) in timestep 10
3814 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 8) in timestep 10
3815 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 8) in timestep 10
3816 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 8) in timestep 10
3817 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 8) in timestep 10
3818 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 8) in timestep 10
3819 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 8) in timestep 10
3820 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 8) in timestep 10
3821 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 8) in timestep 10
3822 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 8) in timestep 10
3823 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 8) in timestep 10
3824 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 8) in timestep 10
3825 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 8) in timestep 10
3826 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 8) in timestep 10
3827 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 8) in timestep 10
3828 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 8) in timestep 10
3829 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 8) in timestep 10
3830 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 8) in timestep 10
3831 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 33 8) in timestep 10
3832 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 8 9) in timestep 10
3833 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 9) in timestep 10
3834 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 9) in timestep 10
3835 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 9) in timestep 10
3836 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 9) in timestep 10
3837 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 9) in timestep 10
3838 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 9) in timestep 10
3839 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 9) in timestep 10
3840 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 9) in timestep 10
3841 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 9) in timestep 10
3842 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 9) in timestep 10
3843 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 9) in timestep 10
3844 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 9) in timestep 10
3845 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 9) in timestep 10
3846 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 9) in timestep 10
3847 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 9) in timestep 10
3848 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 9) in timestep 10
3849 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 9) in timestep 10
3850 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 9) in timestep 10
3851 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 9) in timestep 10
3852 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 9) in timestep 10
3853 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 9) in timestep 10
3854 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 30 9) in timestep 10
3855 5.8290E-05 4.7484E-01 4.7484E-01 3.1477E-05 4.8183E-01 4.5913E-01 4.8129E-01 4.6036E-01
3856 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 9) in timestep 10
3857 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 9) in timestep 10
3858 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 10) in timestep 10
3859 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 10) in timestep 10
3860 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 10) in timestep 10
3861 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 10) in timestep 10
3862 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 10) in timestep 10
3863 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 10) in timestep 10
3864 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 10) in timestep 10
3865 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 10) in timestep 10
3866 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 10) in timestep 10
3867 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 10) in timestep 10
3868 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 10) in timestep 10
3869 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 10) in timestep 10
3870 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 10) in timestep 10
3871 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 10) in timestep 10
3872 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 10) in timestep 10
3873 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 10) in timestep 10
3874 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 26 10) in timestep 10
3875 7.6603E-05 4.6758E-01 4.6758E-01 5.1942E-05 4.7950E-01 4.5576E-01 4.7486E-01 4.6036E-01
3876 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 10) in timestep 10
3877 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 10) in timestep 10
3878 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 10) in timestep 10
3879 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 29 10) in timestep 10
3880 6.4783E-05 4.6752E-01 4.6752E-01 3.2466E-05 4.8514E-01 4.5760E-01 4.8023E-01 4.6036E-01
3881 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 10) in timestep 10
3882 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 11) in timestep 10
3883 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 11) in timestep 10
3884 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 11) in timestep 10
3885 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 11) in timestep 10
3886 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 11) in timestep 10
3887 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 11) in timestep 10
3888 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 11) in timestep 10
3889 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 11) in timestep 10
3890 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 11) in timestep 10
3891 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 11) in timestep 10
3892 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 11) in timestep 10
3893 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 11) in timestep 10
3894 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 11) in timestep 10
3895 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 11) in timestep 10
3896 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 11) in timestep 10
3897 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 11) in timestep 10
3898 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 13) in timestep 10
3899 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 13) in timestep 10
3900 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 13) in timestep 10
3901 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 13) in timestep 10
3902 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 13) in timestep 10
3903 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 13) in timestep 10
3904 (PID.TID 0000.0001) // =======================================================
3905 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
3906 (PID.TID 0000.0001) // =======================================================
3907 (PID.TID 0000.0001) %MON seaice_tsnumber = 11
3908 (PID.TID 0000.0001) %MON seaice_time_sec = 1.9800000000000E+04
3909 (PID.TID 0000.0001) %MON seaice_uice_max = 6.7321629191521E-01
3910 (PID.TID 0000.0001) %MON seaice_uice_min = 3.1289310016742E-01
3911 (PID.TID 0000.0001) %MON seaice_uice_mean = 4.4130726213752E-01
3912 (PID.TID 0000.0001) %MON seaice_uice_sd = 9.2772315456330E-02
3913 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.8990782156705E-04
3914 (PID.TID 0000.0001) %MON seaice_vice_max = 1.2034845668412E-01
3915 (PID.TID 0000.0001) %MON seaice_vice_min = -1.7334529944150E-01
3916 (PID.TID 0000.0001) %MON seaice_vice_mean = -2.6123136143018E-02
3917 (PID.TID 0000.0001) %MON seaice_vice_sd = 5.5485935827895E-02
3918 (PID.TID 0000.0001) %MON seaice_vice_del2 = 9.3983522880380E-05
3919 (PID.TID 0000.0001) %MON seaice_area_max = 9.9998493898273E-01
3920 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
3921 (PID.TID 0000.0001) %MON seaice_area_mean = 9.1854087621309E-01
3922 (PID.TID 0000.0001) %MON seaice_area_sd = 2.2156004513772E-01
3923 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.5155469510755E-03
3924 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6240488913442E+00
3925 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
3926 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9218688025146E+00
3927 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.1991663013731E+00
3928 (PID.TID 0000.0001) %MON seaice_heff_del2 = 1.0081125651861E-03
3929 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
3930 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
3931 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
3932 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
3933 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
3934 (PID.TID 0000.0001) // =======================================================
3935 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
3936 (PID.TID 0000.0001) // =======================================================
3937 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 1 4.81923212E-01 1.37544208E-01
3938 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.44784762E+02 6.07526285E+01
3939 SEAICE_LSR (ipass= 1) iters,dU,Resid= 1500 7.43371858E-06 4.30400896E-01
3940 SEAICE_LSR (ipass= 1) iters,dV,Resid= 1500 1.13592202E-09 4.02489512E-07
3941 SEAICE_LSR: Residual Initial ipass,Uice,Vice= 2 4.73413931E-01 1.38900070E-01
3942 SEAICE_LSR: Residual FrDrift U_fd,V_fd= 2.52370664E+02 5.94195483E+01
3943 SEAICE_LSR (ipass= 2) iters,dU,Resid= 1500 6.79935390E-06 4.03361492E-01
3944 SEAICE_LSR (ipass= 2) iters,dV,Resid= 1500 1.02788431E-09 3.82535422E-07
3945 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 1 in timestep 11
3946 (PID.TID 0000.0001) SEAICE_DO_RIDGING: Repeat ridging after iteration 2 in timestep 11
3947 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 21) in timestep 11
3948 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 21) in timestep 11
3949 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 1) in timestep 11
3950 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 2) in timestep 11
3951 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 2) in timestep 11
3952 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 3) in timestep 11
3953 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 3) in timestep 11
3954 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 3) in timestep 11
3955 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 3) in timestep 11
3956 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 3) in timestep 11
3957 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 7 4) in timestep 11
3958 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 4) in timestep 11
3959 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 4) in timestep 11
3960 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 5) in timestep 11
3961 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 5) in timestep 11
3962 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 5) in timestep 11
3963 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 5) in timestep 11
3964 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 5) in timestep 11
3965 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 5) in timestep 11
3966 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 5) in timestep 11
3967 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 5) in timestep 11
3968 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 5) in timestep 11
3969 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 5) in timestep 11
3970 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 5) in timestep 11
3971 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 5) in timestep 11
3972 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 5) in timestep 11
3973 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 5) in timestep 11
3974 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 5) in timestep 11
3975 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 5) in timestep 11
3976 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 6) in timestep 11
3977 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 6) in timestep 11
3978 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 6) in timestep 11
3979 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 6) in timestep 11
3980 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 6) in timestep 11
3981 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 6) in timestep 11
3982 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 6) in timestep 11
3983 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 6) in timestep 11
3984 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 6) in timestep 11
3985 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 6) in timestep 11
3986 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 6) in timestep 11
3987 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 6) in timestep 11
3988 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 6) in timestep 11
3989 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 6) in timestep 11
3990 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 6) in timestep 11
3991 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 6) in timestep 11
3992 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 6) in timestep 11
3993 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 6) in timestep 11
3994 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 34 6) in timestep 11
3995 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 7 7) in timestep 11
3996 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 7) in timestep 11
3997 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 7) in timestep 11
3998 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 7) in timestep 11
3999 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 7) in timestep 11
4000 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 7) in timestep 11
4001 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 7) in timestep 11
4002 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 7) in timestep 11
4003 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 7) in timestep 11
4004 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 7) in timestep 11
4005 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 7) in timestep 11
4006 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 7) in timestep 11
4007 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 7) in timestep 11
4008 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 7) in timestep 11
4009 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 7) in timestep 11
4010 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 7) in timestep 11
4011 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 7) in timestep 11
4012 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 7) in timestep 11
4013 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 7) in timestep 11
4014 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 7) in timestep 11
4015 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 7) in timestep 11
4016 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 7) in timestep 11
4017 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 8 8) in timestep 11
4018 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 8) in timestep 11
4019 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 8) in timestep 11
4020 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 8) in timestep 11
4021 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 8) in timestep 11
4022 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 8) in timestep 11
4023 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 8) in timestep 11
4024 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 8) in timestep 11
4025 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 8) in timestep 11
4026 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 8) in timestep 11
4027 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 8) in timestep 11
4028 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 8) in timestep 11
4029 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 8) in timestep 11
4030 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 8) in timestep 11
4031 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 8) in timestep 11
4032 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 8) in timestep 11
4033 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 8) in timestep 11
4034 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 8) in timestep 11
4035 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 8) in timestep 11
4036 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 8) in timestep 11
4037 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 8) in timestep 11
4038 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 8) in timestep 11
4039 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 8) in timestep 11
4040 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 7 9) in timestep 11
4041 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 8 9) in timestep 11
4042 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 9) in timestep 11
4043 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 9) in timestep 11
4044 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 9) in timestep 11
4045 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 9) in timestep 11
4046 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 9) in timestep 11
4047 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 9) in timestep 11
4048 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 9) in timestep 11
4049 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 9) in timestep 11
4050 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 9) in timestep 11
4051 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 9) in timestep 11
4052 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 9) in timestep 11
4053 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 9) in timestep 11
4054 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 9) in timestep 11
4055 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 9) in timestep 11
4056 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 9) in timestep 11
4057 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 9) in timestep 11
4058 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 9) in timestep 11
4059 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 9) in timestep 11
4060 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 9) in timestep 11
4061 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 9) in timestep 11
4062 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 9) in timestep 11
4063 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 9) in timestep 11
4064 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 31 9) in timestep 11
4065 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 32 9) in timestep 11
4066 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 33 9) in timestep 11
4067 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 34 9) in timestep 11
4068 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 9 10) in timestep 11
4069 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 9 10) in timestep 11
4070 4.0010E-05 4.6593E-01 4.6593E-01 4.6439E-05 4.7020E-01 4.5285E-01 4.6774E-01 4.6036E-01
4071 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 10) in timestep 11
4072 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 10 10) in timestep 11
4073 5.5877E-05 4.6594E-01 4.6594E-01 5.2031E-05 4.7285E-01 4.5511E-01 4.6950E-01 4.6036E-01
4074 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 10) in timestep 11
4075 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 10) in timestep 11
4076 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 10) in timestep 11
4077 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 10) in timestep 11
4078 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 10) in timestep 11
4079 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 10) in timestep 11
4080 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 10) in timestep 11
4081 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 10) in timestep 11
4082 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 10) in timestep 11
4083 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 10) in timestep 11
4084 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 10) in timestep 11
4085 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 10) in timestep 11
4086 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 10) in timestep 11
4087 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 10) in timestep 11
4088 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 10) in timestep 11
4089 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 10) in timestep 11
4090 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 10) in timestep 11
4091 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 10) in timestep 11
4092 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 10) in timestep 11
4093 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 10) in timestep 11
4094 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 10 11) in timestep 11
4095 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 11) in timestep 11
4096 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 11) in timestep 11
4097 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 11) in timestep 11
4098 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 11) in timestep 11
4099 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 11) in timestep 11
4100 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 11) in timestep 11
4101 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 11) in timestep 11
4102 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 11) in timestep 11
4103 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 11) in timestep 11
4104 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 11) in timestep 11
4105 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 11) in timestep 11
4106 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 11) in timestep 11
4107 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 11) in timestep 11
4108 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 11) in timestep 11
4109 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 11) in timestep 11
4110 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 11) in timestep 11
4111 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 11) in timestep 11
4112 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 28 11) in timestep 11
4113 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 29 11) in timestep 11
4114 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 30 11) in timestep 11
4115 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 30 11) in timestep 11
4116 4.0305E-05 4.6605E-01 4.6605E-01 5.3936E-05 4.6789E-01 4.5055E-01 4.6673E-01 4.6036E-01
4117 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 11 12) in timestep 11
4118 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 12 12) in timestep 11
4119 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 13 12) in timestep 11
4120 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 14 12) in timestep 11
4121 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 12) in timestep 11
4122 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 12) in timestep 11
4123 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 12) in timestep 11
4124 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 12) in timestep 11
4125 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 12) in timestep 11
4126 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 12) in timestep 11
4127 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 12) in timestep 11
4128 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 22 12) in timestep 11
4129 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 22 12) in timestep 11
4130 8.3814E-05 4.6746E-01 4.6746E-01 5.8929E-05 4.7913E-01 4.5584E-01 4.7459E-01 4.6036E-01
4131 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 23 12) in timestep 11
4132 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 23 12) in timestep 11
4133 7.7460E-05 4.6661E-01 4.6661E-01 5.9420E-05 4.7794E-01 4.5612E-01 4.7336E-01 4.6036E-01
4134 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 24 12) in timestep 11
4135 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 25 12) in timestep 11
4136 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 12) in timestep 11
4137 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 26 12) in timestep 11
4138 6.6446E-05 4.6725E-01 4.6725E-01 4.3537E-05 4.8018E-01 4.5643E-01 4.7548E-01 4.6036E-01
4139 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 27 12) in timestep 11
4140 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 27 12) in timestep 11
4141 6.7090E-05 4.6656E-01 4.6656E-01 3.3739E-05 4.8456E-01 4.5736E-01 4.7869E-01 4.6036E-01
4142 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 15 13) in timestep 11
4143 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 16 13) in timestep 11
4144 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 17 13) in timestep 11
4145 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 18 13) in timestep 11
4146 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 19 13) in timestep 11
4147 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 20 13) in timestep 11
4148 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 20 13) in timestep 11
4149 6.3900E-05 4.6607E-01 4.6607E-01 4.8398E-05 4.7783E-01 4.5537E-01 4.7234E-01 4.6036E-01
4150 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 21 13) in timestep 11
4151 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 21 13) in timestep 11
4152 5.0188E-05 4.6679E-01 4.6679E-01 5.7240E-05 4.7218E-01 4.5302E-01 4.6931E-01 4.6036E-01
4153 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k) >= hLimitNew(k) for category 1 at ( 26 13) in timestep 11
4154 (PID.TID 0000.0001) SEAICE_ITD_REMAP: hActual(k+1) <= hLimitNew(k) for category 1 at ( 26 13) in timestep 11
4155 3.4310E-05 4.6676E-01 4.6676E-01 4.2079E-05 4.7043E-01 4.5200E-01 4.6835E-01 4.6036E-01
4156 (PID.TID 0000.0001) // =======================================================
4157 (PID.TID 0000.0001) // Begin MONITOR dynamic field statistics
4158 (PID.TID 0000.0001) // =======================================================
4159 (PID.TID 0000.0001) %MON time_tsnumber = 12
4160 (PID.TID 0000.0001) %MON time_secondsf = 2.1600000000000E+04
4161 (PID.TID 0000.0001) %MON dynstat_eta_max = 1.4855271423662E-02
4162 (PID.TID 0000.0001) %MON dynstat_eta_min = -1.5547625271979E-02
4163 (PID.TID 0000.0001) %MON dynstat_eta_mean = -6.8609663050809E-19
4164 (PID.TID 0000.0001) %MON dynstat_eta_sd = 5.6185276903544E-03
4165 (PID.TID 0000.0001) %MON dynstat_eta_del2 = 3.4210904025025E-06
4166 (PID.TID 0000.0001) %MON dynstat_uvel_max = 5.4694595665363E-01
4167 (PID.TID 0000.0001) %MON dynstat_uvel_min = 8.1797628424127E-02
4168 (PID.TID 0000.0001) %MON dynstat_uvel_mean = 3.2603530929361E-01
4169 (PID.TID 0000.0001) %MON dynstat_uvel_sd = 8.4661197148990E-02
4170 (PID.TID 0000.0001) %MON dynstat_uvel_del2 = 1.3392731599312E-04
4171 (PID.TID 0000.0001) %MON dynstat_vvel_max = 2.2780617104059E-01
4172 (PID.TID 0000.0001) %MON dynstat_vvel_min = -1.4793000868950E-01
4173 (PID.TID 0000.0001) %MON dynstat_vvel_mean = -3.2450632095700E-04
4174 (PID.TID 0000.0001) %MON dynstat_vvel_sd = 6.0970835295293E-02
4175 (PID.TID 0000.0001) %MON dynstat_vvel_del2 = 8.1836652323282E-05
4176 (PID.TID 0000.0001) %MON dynstat_wvel_max = 1.6555698845343E-04
4177 (PID.TID 0000.0001) %MON dynstat_wvel_min = -2.4393468746960E-04
4178 (PID.TID 0000.0001) %MON dynstat_wvel_mean = -1.8006686469634E-21
4179 (PID.TID 0000.0001) %MON dynstat_wvel_sd = 1.8006622332191E-05
4180 (PID.TID 0000.0001) %MON dynstat_wvel_del2 = 3.4047422448573E-07
4181 (PID.TID 0000.0001) %MON dynstat_theta_max = -1.5751098890513E+00
4182 (PID.TID 0000.0001) %MON dynstat_theta_min = -1.6340295440875E+00
4183 (PID.TID 0000.0001) %MON dynstat_theta_mean = -1.6300996407746E+00
4184 (PID.TID 0000.0001) %MON dynstat_theta_sd = 7.9149536676971E-03
4185 (PID.TID 0000.0001) %MON dynstat_theta_del2 = 2.7747256716343E-05
4186 (PID.TID 0000.0001) %MON dynstat_salt_max = 3.0000000000000E+01
4187 (PID.TID 0000.0001) %MON dynstat_salt_min = 3.0000000000000E+01
4188 (PID.TID 0000.0001) %MON dynstat_salt_mean = 3.0000000000000E+01
4189 (PID.TID 0000.0001) %MON dynstat_salt_sd = 0.0000000000000E+00
4190 (PID.TID 0000.0001) %MON dynstat_salt_del2 = 0.0000000000000E+00
4191 (PID.TID 0000.0001) %MON trAdv_CFL_u_max = 1.9690054439531E-01
4192 (PID.TID 0000.0001) %MON trAdv_CFL_v_max = 8.2010221574612E-02
4193 (PID.TID 0000.0001) %MON trAdv_CFL_w_max = 2.9800257921617E-02
4194 (PID.TID 0000.0001) %MON advcfl_uvel_max = 1.9690054439531E-01
4195 (PID.TID 0000.0001) %MON advcfl_vvel_max = 8.2010221574612E-02
4196 (PID.TID 0000.0001) %MON advcfl_wvel_max = 8.7816487489057E-02
4197 (PID.TID 0000.0001) %MON advcfl_W_hf_max = 0.0000000000000E+00
4198 (PID.TID 0000.0001) %MON pe_b_mean = 1.5484032096270E-05
4199 (PID.TID 0000.0001) %MON ke_max = 1.4564487757410E-01
4200 (PID.TID 0000.0001) %MON ke_mean = 5.8130401708830E-02
4201 (PID.TID 0000.0001) %MON ke_vol = 6.9500000000000E+11
4202 (PID.TID 0000.0001) %MON vort_r_min = -1.4191202448594E-04
4203 (PID.TID 0000.0001) %MON vort_r_max = 8.9657385579761E-05
4204 (PID.TID 0000.0001) %MON vort_a_mean = -6.5586096803907E-22
4205 (PID.TID 0000.0001) %MON vort_a_sd = 1.5889649807104E-05
4206 (PID.TID 0000.0001) %MON vort_p_mean = -6.8228760045090E-22
4207 (PID.TID 0000.0001) %MON vort_p_sd = 3.0669223294758E-05
4208 (PID.TID 0000.0001) %MON surfExpan_theta_mean = 2.0050663764520E-08
4209 (PID.TID 0000.0001) %MON surfExpan_salt_mean = 1.6750406018264E-20
4210 (PID.TID 0000.0001) // =======================================================
4211 (PID.TID 0000.0001) // End MONITOR dynamic field statistics
4212 (PID.TID 0000.0001) // =======================================================
4213 (PID.TID 0000.0001) // =======================================================
4214 (PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
4215 (PID.TID 0000.0001) // =======================================================
4216 (PID.TID 0000.0001) %MON seaice_tsnumber = 12
4217 (PID.TID 0000.0001) %MON seaice_time_sec = 2.1600000000000E+04
4218 (PID.TID 0000.0001) %MON seaice_uice_max = 6.7376158663174E-01
4219 (PID.TID 0000.0001) %MON seaice_uice_min = 3.1281567902083E-01
4220 (PID.TID 0000.0001) %MON seaice_uice_mean = 4.4795621668762E-01
4221 (PID.TID 0000.0001) %MON seaice_uice_sd = 8.8205811669295E-02
4222 (PID.TID 0000.0001) %MON seaice_uice_del2 = 1.9456733274741E-04
4223 (PID.TID 0000.0001) %MON seaice_vice_max = 1.2096267141006E-01
4224 (PID.TID 0000.0001) %MON seaice_vice_min = -1.7086775562559E-01
4225 (PID.TID 0000.0001) %MON seaice_vice_mean = -2.4912457794876E-02
4226 (PID.TID 0000.0001) %MON seaice_vice_sd = 5.4870949009936E-02
4227 (PID.TID 0000.0001) %MON seaice_vice_del2 = 9.3260878634333E-05
4228 (PID.TID 0000.0001) %MON seaice_area_max = 9.9998361535629E-01
4229 (PID.TID 0000.0001) %MON seaice_area_min = 0.0000000000000E+00
4230 (PID.TID 0000.0001) %MON seaice_area_mean = 9.1588808978220E-01
4231 (PID.TID 0000.0001) %MON seaice_area_sd = 2.2416628337219E-01
4232 (PID.TID 0000.0001) %MON seaice_area_del2 = 1.5373918821092E-03
4233 (PID.TID 0000.0001) %MON seaice_heff_max = 7.6240023929793E+00
4234 (PID.TID 0000.0001) %MON seaice_heff_min = 0.0000000000000E+00
4235 (PID.TID 0000.0001) %MON seaice_heff_mean = 1.9217856601190E+00
4236 (PID.TID 0000.0001) %MON seaice_heff_sd = 2.1981559481990E+00
4237 (PID.TID 0000.0001) %MON seaice_heff_del2 = 1.0620776124092E-03
4238 (PID.TID 0000.0001) %MON seaice_hsnow_max = 0.0000000000000E+00
4239 (PID.TID 0000.0001) %MON seaice_hsnow_min = 0.0000000000000E+00
4240 (PID.TID 0000.0001) %MON seaice_hsnow_mean = 0.0000000000000E+00
4241 (PID.TID 0000.0001) %MON seaice_hsnow_sd = 0.0000000000000E+00
4242 (PID.TID 0000.0001) %MON seaice_hsnow_del2 = 0.0000000000000E+00
4243 (PID.TID 0000.0001) // =======================================================
4244 (PID.TID 0000.0001) // End MONITOR SEAICE statistics
4245 (PID.TID 0000.0001) // =======================================================
4246 Compute Stats, Diag. # 145 SIarea vol( 0 ): 2.085E+11 Parms: SM M1
4247 Compute Stats, Diag. # 148 SIheff vol( 0 ): 2.085E+11 Parms: SM M1
4248 Compute Stats, Diag. # 150 SIhsnow vol( 0 ): 2.085E+11 Parms: SM M1
4249 Compute Stats, Diag. # 154 SIuice vol( 0 ): 2.070E+11 Parms: UU M1
4250 Compute Stats, Diag. # 155 SIvice vol( 0 ): 2.025E+11 Parms: VV M1
4251 (PID.TID 0000.0001) DIAGSTATS_CLOSE_IO: close file: iceStDiag.0000000000.txt , unit= 9
4252 (PID.TID 0000.0001) %CHECKPOINT 12 ckptA
4253 (PID.TID 0000.0001) Seconds in section "ALL [THE_MODEL_MAIN]":
4254 (PID.TID 0000.0001) User time: 56.816215515136719
4255 (PID.TID 0000.0001) System time: 1.6617000801488757E-002
4256 (PID.TID 0000.0001) Wall clock time: 56.843737840652466
4257 (PID.TID 0000.0001) No. starts: 1
4258 (PID.TID 0000.0001) No. stops: 1
4259 (PID.TID 0000.0001) Seconds in section "INITIALISE_FIXED [THE_MODEL_MAIN]":
4260 (PID.TID 0000.0001) User time: 4.0564998984336853E-002
4261 (PID.TID 0000.0001) System time: 6.4900005236268044E-004
4262 (PID.TID 0000.0001) Wall clock time: 4.1270017623901367E-002
4263 (PID.TID 0000.0001) No. starts: 1
4264 (PID.TID 0000.0001) No. stops: 1
4265 (PID.TID 0000.0001) Seconds in section "THE_MAIN_LOOP [THE_MODEL_MAIN]":
4266 (PID.TID 0000.0001) User time: 56.775630887597799
4267 (PID.TID 0000.0001) System time: 1.5940000768750906E-002
4268 (PID.TID 0000.0001) Wall clock time: 56.802426099777222
4269 (PID.TID 0000.0001) No. starts: 1
4270 (PID.TID 0000.0001) No. stops: 1
4271 (PID.TID 0000.0001) Seconds in section "INITIALISE_VARIA [THE_MAIN_LOOP]":
4272 (PID.TID 0000.0001) User time: 6.3563000410795212E-002
4273 (PID.TID 0000.0001) System time: 0.0000000000000000
4274 (PID.TID 0000.0001) Wall clock time: 6.3522100448608398E-002
4275 (PID.TID 0000.0001) No. starts: 1
4276 (PID.TID 0000.0001) No. stops: 1
4277 (PID.TID 0000.0001) Seconds in section "MAIN LOOP [THE_MAIN_LOOP]":
4278 (PID.TID 0000.0001) User time: 56.712053254246712
4279 (PID.TID 0000.0001) System time: 1.5939000528305769E-002
4280 (PID.TID 0000.0001) Wall clock time: 56.738878965377808
4281 (PID.TID 0000.0001) No. starts: 1
4282 (PID.TID 0000.0001) No. stops: 1
4283 (PID.TID 0000.0001) Seconds in section "MAIN_DO_LOOP [THE_MAIN_LOOP]":
4284 (PID.TID 0000.0001) User time: 56.711986497044563
4285 (PID.TID 0000.0001) System time: 1.5939000528305769E-002
4286 (PID.TID 0000.0001) Wall clock time: 56.738787651062012
4287 (PID.TID 0000.0001) No. starts: 12
4288 (PID.TID 0000.0001) No. stops: 12
4289 (PID.TID 0000.0001) Seconds in section "FORWARD_STEP [MAIN_DO_LOOP]":
4290 (PID.TID 0000.0001) User time: 56.711789563298225
4291 (PID.TID 0000.0001) System time: 1.5939000528305769E-002
4292 (PID.TID 0000.0001) Wall clock time: 56.738614082336426
4293 (PID.TID 0000.0001) No. starts: 12
4294 (PID.TID 0000.0001) No. stops: 12
4295 (PID.TID 0000.0001) Seconds in section "DO_STATEVARS_DIAGS [FORWARD_STEP]":
4296 (PID.TID 0000.0001) User time: 2.2495307028293610E-002
4297 (PID.TID 0000.0001) System time: 2.3999717086553574E-005
4298 (PID.TID 0000.0001) Wall clock time: 2.2518396377563477E-002
4299 (PID.TID 0000.0001) No. starts: 36
4300 (PID.TID 0000.0001) No. stops: 36
4301 (PID.TID 0000.0001) Seconds in section "LOAD_FIELDS_DRIVER [FORWARD_STEP]":
4302 (PID.TID 0000.0001) User time: 9.2006526887416840E-002
4303 (PID.TID 0000.0001) System time: 0.0000000000000000
4304 (PID.TID 0000.0001) Wall clock time: 9.2019557952880859E-002
4305 (PID.TID 0000.0001) No. starts: 12
4306 (PID.TID 0000.0001) No. stops: 12
4307 (PID.TID 0000.0001) Seconds in section "EXF_GETFORCING [LOAD_FLDS_DRIVER]":
4308 (PID.TID 0000.0001) User time: 9.1649711132049561E-002
4309 (PID.TID 0000.0001) System time: 0.0000000000000000
4310 (PID.TID 0000.0001) Wall clock time: 9.1657876968383789E-002
4311 (PID.TID 0000.0001) No. starts: 12
4312 (PID.TID 0000.0001) No. stops: 12
4313 (PID.TID 0000.0001) Seconds in section "EXTERNAL_FLDS_LOAD [LOAD_FLDS_DRIVER]":
4314 (PID.TID 0000.0001) User time: 1.1450052261352539E-004
4315 (PID.TID 0000.0001) System time: 0.0000000000000000
4316 (PID.TID 0000.0001) Wall clock time: 9.3936920166015625E-005
4317 (PID.TID 0000.0001) No. starts: 12
4318 (PID.TID 0000.0001) No. stops: 12
4319 (PID.TID 0000.0001) Seconds in section "DO_ATMOSPHERIC_PHYS [FORWARD_STEP]":
4320 (PID.TID 0000.0001) User time: 9.1716647148132324E-005
4321 (PID.TID 0000.0001) System time: 0.0000000000000000
4322 (PID.TID 0000.0001) Wall clock time: 9.1791152954101562E-005
4323 (PID.TID 0000.0001) No. starts: 12
4324 (PID.TID 0000.0001) No. stops: 12
4325 (PID.TID 0000.0001) Seconds in section "DO_OCEANIC_PHYS [FORWARD_STEP]":
4326 (PID.TID 0000.0001) User time: 56.472195163369179
4327 (PID.TID 0000.0001) System time: 1.5914000570774078E-002
4328 (PID.TID 0000.0001) Wall clock time: 56.498862504959106
4329 (PID.TID 0000.0001) No. starts: 12
4330 (PID.TID 0000.0001) No. stops: 12
4331 (PID.TID 0000.0001) Seconds in section "SEAICE_MODEL [DO_OCEANIC_PHYS]":
4332 (PID.TID 0000.0001) User time: 56.451132103800774
4333 (PID.TID 0000.0001) System time: 1.5910999849438667E-002
4334 (PID.TID 0000.0001) Wall clock time: 56.477823019027710
4335 (PID.TID 0000.0001) No. starts: 12
4336 (PID.TID 0000.0001) No. stops: 12
4337 (PID.TID 0000.0001) Seconds in section "SEAICE_DYNSOLVER [SEAICE_MODEL]":
4338 (PID.TID 0000.0001) User time: 53.921195179224014
4339 (PID.TID 0000.0001) System time: 1.5894001349806786E-002
4340 (PID.TID 0000.0001) Wall clock time: 53.947236537933350
4341 (PID.TID 0000.0001) No. starts: 12
4342 (PID.TID 0000.0001) No. stops: 12
4343 (PID.TID 0000.0001) Seconds in section "BLOCKING_EXCHANGES [FORWARD_STEP]":
4344 (PID.TID 0000.0001) User time: 4.7769546508789062E-003
4345 (PID.TID 0000.0001) System time: 0.0000000000000000
4346 (PID.TID 0000.0001) Wall clock time: 4.7500133514404297E-003
4347 (PID.TID 0000.0001) No. starts: 24
4348 (PID.TID 0000.0001) No. stops: 24
4349 (PID.TID 0000.0001) Seconds in section "THERMODYNAMICS [FORWARD_STEP]":
4350 (PID.TID 0000.0001) User time: 4.2881965637207031E-002
4351 (PID.TID 0000.0001) System time: 0.0000000000000000
4352 (PID.TID 0000.0001) Wall clock time: 4.2893171310424805E-002
4353 (PID.TID 0000.0001) No. starts: 12
4354 (PID.TID 0000.0001) No. stops: 12
4355 (PID.TID 0000.0001) Seconds in section "TRC_CORRECTION_STEP [FORWARD_STEP]":
4356 (PID.TID 0000.0001) User time: 1.0991096496582031E-004
4357 (PID.TID 0000.0001) System time: 0.0000000000000000
4358 (PID.TID 0000.0001) Wall clock time: 8.9645385742187500E-005
4359 (PID.TID 0000.0001) No. starts: 12
4360 (PID.TID 0000.0001) No. stops: 12
4361 (PID.TID 0000.0001) Seconds in section "MONITOR [FORWARD_STEP]":
4362 (PID.TID 0000.0001) User time: 7.6606273651123047E-003
4363 (PID.TID 0000.0001) System time: 0.0000000000000000
4364 (PID.TID 0000.0001) Wall clock time: 7.6494216918945312E-003
4365 (PID.TID 0000.0001) No. starts: 12
4366 (PID.TID 0000.0001) No. stops: 12
4367 (PID.TID 0000.0001) Seconds in section "DO_THE_MODEL_IO [FORWARD_STEP]":
4368 (PID.TID 0000.0001) User time: 5.8747053146362305E-002
4369 (PID.TID 0000.0001) System time: 0.0000000000000000
4370 (PID.TID 0000.0001) Wall clock time: 5.8776378631591797E-002
4371 (PID.TID 0000.0001) No. starts: 12
4372 (PID.TID 0000.0001) No. stops: 12
4373 (PID.TID 0000.0001) Seconds in section "DO_WRITE_PICKUP [FORWARD_STEP]":
4374 (PID.TID 0000.0001) User time: 9.6728801727294922E-003
4375 (PID.TID 0000.0001) System time: 0.0000000000000000
4376 (PID.TID 0000.0001) Wall clock time: 9.6693038940429688E-003
4377 (PID.TID 0000.0001) No. starts: 12
4378 (PID.TID 0000.0001) No. stops: 12
4379 (PID.TID 0000.0001) // ======================================================
4380 (PID.TID 0000.0001) // Tile <-> Tile communication statistics
4381 (PID.TID 0000.0001) // ======================================================
4382 (PID.TID 0000.0001) // o Tile number: 000001
4383 (PID.TID 0000.0001) // No. X exchanges = 0
4384 (PID.TID 0000.0001) // Max. X spins = 0
4385 (PID.TID 0000.0001) // Min. X spins = 1000000000
4386 (PID.TID 0000.0001) // Total. X spins = 0
4387 (PID.TID 0000.0001) // Avg. X spins = 0.00E+00
4388 (PID.TID 0000.0001) // No. Y exchanges = 0
4389 (PID.TID 0000.0001) // Max. Y spins = 0
4390 (PID.TID 0000.0001) // Min. Y spins = 1000000000
4391 (PID.TID 0000.0001) // Total. Y spins = 0
4392 (PID.TID 0000.0001) // Avg. Y spins = 0.00E+00
4393 (PID.TID 0000.0001) // o Tile number: 000002
4394 (PID.TID 0000.0001) // No. X exchanges = 0
4395 (PID.TID 0000.0001) // Max. X spins = 0
4396 (PID.TID 0000.0001) // Min. X spins = 1000000000
4397 (PID.TID 0000.0001) // Total. X spins = 0
4398 (PID.TID 0000.0001) // Avg. X spins = 0.00E+00
4399 (PID.TID 0000.0001) // No. Y exchanges = 0
4400 (PID.TID 0000.0001) // Max. Y spins = 0
4401 (PID.TID 0000.0001) // Min. Y spins = 1000000000
4402 (PID.TID 0000.0001) // Total. Y spins = 0
4403 (PID.TID 0000.0001) // Avg. Y spins = 0.00E+00
4404 (PID.TID 0000.0001) // o Tile number: 000003
4405 (PID.TID 0000.0001) // No. X exchanges = 0
4406 (PID.TID 0000.0001) // Max. X spins = 0
4407 (PID.TID 0000.0001) // Min. X spins = 1000000000
4408 (PID.TID 0000.0001) // Total. X spins = 0
4409 (PID.TID 0000.0001) // Avg. X spins = 0.00E+00
4410 (PID.TID 0000.0001) // No. Y exchanges = 0
4411 (PID.TID 0000.0001) // Max. Y spins = 0
4412 (PID.TID 0000.0001) // Min. Y spins = 1000000000
4413 (PID.TID 0000.0001) // Total. Y spins = 0
4414 (PID.TID 0000.0001) // Avg. Y spins = 0.00E+00
4415 (PID.TID 0000.0001) // o Tile number: 000004
4416 (PID.TID 0000.0001) // No. X exchanges = 0
4417 (PID.TID 0000.0001) // Max. X spins = 0
4418 (PID.TID 0000.0001) // Min. X spins = 1000000000
4419 (PID.TID 0000.0001) // Total. X spins = 0
4420 (PID.TID 0000.0001) // Avg. X spins = 0.00E+00
4421 (PID.TID 0000.0001) // No. Y exchanges = 0
4422 (PID.TID 0000.0001) // Max. Y spins = 0
4423 (PID.TID 0000.0001) // Min. Y spins = 1000000000
4424 (PID.TID 0000.0001) // Total. Y spins = 0
4425 (PID.TID 0000.0001) // Avg. Y spins = 0.00E+00
4426 (PID.TID 0000.0001) // o Thread number: 000001
4427 (PID.TID 0000.0001) // No. barriers = 57106
4428 (PID.TID 0000.0001) // Max. barrier spins = 1
4429 (PID.TID 0000.0001) // Min. barrier spins = 1
4430 (PID.TID 0000.0001) // Total barrier spins = 57106
4431 (PID.TID 0000.0001) // Avg. barrier spins = 1.00E+00
4432 PROGRAM MAIN: Execution ended Normally
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