def initialize_barrow_cohorts(self): print '=================================== ' print ' Initializing Lake & Pond Properties' print '====================================' initialize.LakePond(self) set_lake_pond_depth.set_lake_pond_depth(self) set_lake_ice_depth_constant.set_lake_ice_depth_constant(self) set_ice_thickness_array.set_ice_thickness_array(self) climate_expansion_arrays.set_climate_expansion_arrays(self) set_pond_growth_array.set_pond_growth_array(self) print '=====================================' print ' Initializing Terrestrial Properties' print '=====================================' initialize.Terrestrial_Barrow(self) read_ice_content.read_ice_content(self) read_drainage_efficiency.read_drainage_efficiency(self) read_initial_ALD.read_initial_ALD(self) set_ALD_constant.set_ALD_constant(self) set_ALD_array.set_ALD_array(self) set_protective_layer.set_protective_layer(self) set_initial_cumulative_probability.set_initial_cumulative_probability(self) # Initializing Terrestrial Cohort Properties initialize.Wet_NPG(self) initialize.Wet_LCP(self) initialize.Wet_CLC(self) initialize.Wet_FCP(self) initialize.Wet_HCP(self) # Other needed information [in the future] initial_cohort_age.initial_cohort_age(self)
def initialize_barrow_cohorts(self): print '=================================== ' print ' Initializing Lake & Pond Properties' print '====================================' initialize.LakePond(self) set_lake_pond_depth.set_lake_pond_depth(self) set_lake_ice_depth_constant.set_lake_ice_depth_constant(self) set_ice_thickness_array.set_ice_thickness_array(self) climate_expansion_arrays.set_climate_expansion_arrays(self) set_pond_growth_array.set_pond_growth_array(self) print '=====================================' print ' Initializing Terrestrial Properties' print '=====================================' initialize.Terrestrial_Barrow(self) read_ice_content.read_ice_content(self) read_drainage_efficiency.read_drainage_efficiency(self) read_initial_ALD.read_initial_ALD(self) set_ALD_constant.set_ALD_constant(self) set_ALD_array.set_ALD_array(self) set_protective_layer.set_protective_layer(self) set_initial_cumulative_probability.set_initial_cumulative_probability(self) # Initializing Terrestrial Cohort Properties initialize.CLC_WT(self) initialize.CoastalWaters_WT(self) initialize.DrainedSlope_WT(self) initialize.FCP_WT(self) initialize.HCP_WT(self) initialize.LCP_WT(self) initialize.Meadow_WT(self) initialize.NoData_WT(self) initialize.SandDunes_WT(self) initialize.SaturatedBarrens_WT(self) initialize.Shrubs_WT(self) initialize.Urban_WT(self) initial_cohort_age.initial_cohort_age(self)
def run_attm(self): """ Program sequence """ #==================================================== # Initialization Process #==================================================== print '===================' print ' Initializing ATTM' print '===================' read_control.read_control(self) initialize.initialize(self) read_layers.read_layers(self) model_domain.model_domain(self) create_attm_cohort_arrays.create_attm_cohort_arrays(self) if self.Simulation_area.lower() == 'barrow': initial_cohort_population.barrow_initial_cohort_population(self) initial_cohort_check.barrow_initial_cohort_check(self) cohort_present.barrow_cohort_present(self) elif self.Simulation_area.lower() == 'tanana': initial_cohort_population.tanana_initial_cohort_population(self) initial_cohort_check.tanana_initial_cohort_check(self) cohort_present.tanana_cohort_present(self) #======================================= # READ MET Data & Calculate Degree Days #======================================= initialize.Met(self) #++++++++++++++++++++++++++++++++++++++++++++++ # ======================================== # INITIALIZE BARROW COHORT PROPERTIES # ======================================== #++++++++++++++++++++++++++++++++++++++++++++++ if self.Simulation_area.lower() == 'barrow': print '=================================== ' print ' Initializing Lake & Pond Properties' print '====================================' initialize.LakePond(self) set_lake_pond_depth.set_lake_pond_depth(self) set_lake_ice_depth_constant.set_lake_ice_depth_constant(self) set_ice_thickness_array.set_ice_thickness_array(self) climate_expansion_arrays.set_climate_expansion_arrays(self) set_pond_growth_array.set_pond_growth_array(self) print '=====================================' print ' Initializing Terrestrial Properties' print '=====================================' initialize.Terrestrial_Barrow(self) read_ice_content.read_ice_content(self) read_drainage_efficiency.read_drainage_efficiency(self) read_initial_ALD.read_initial_ALD(self) set_ALD_constant.set_ALD_constant(self) set_ALD_array.set_ALD_array(self) set_protective_layer.set_protective_layer(self) set_initial_cumulative_probability.set_initial_cumulative_probability(self) # Initializing Terrestrial Cohort Properties initialize.Wet_NPG(self) initialize.Wet_LCP(self) initialize.Wet_CLC(self) initialize.Wet_FCP(self) initialize.Wet_HCP(self) # Other needed information [in the future] initial_cohort_age.initial_cohort_age(self) elif self.Simulation_area.lower() == 'tanana': print '======================================' print ' Initializing Terrestrial Properties ' print '======================================' initialize.Terrestrial_Tanana(self) print '==================================================' print ' Starting the MAIN LOOP ' print '==================================================' initialize.run(self) for time in range(0, self.stop): if time == 0: if self.Simulation_area.lower() == 'barrow': cohorts.initial_barrow(self) elif self.Simulation_area.lower() == 'tanana': cohorts.initial_tanana(self) print ' at time step: ', time # ++++++++++++++++++++++++++++++++++++++ # Check for significant climatic event # ++++++++++++++++++++++++++++++++++++++ check_climate_event.check_climate_event(self) # ---------------------------------------------------------- # Looping over elements # ---------------------------------------------------------- for element in range(0, self.ATTM_nrows * self.ATTM_ncols): # ---------------------------------------------------- # Define the total fractional area of cohorts for # each element # ---------------------------------------------------- cohort_start = cohort_check.cohort_start(self, element, time) # ---------------------------------------------------- # Expand/Infill lake & ponds by prescribed rates # ---------------------------------------------------- lake_pond_expansion.lake_pond_expansion(self, element) lake_pond_expansion.pond_infill(self, element, time) # ---------------------------------------------------------- # Set active layer depth # --------------------------------------------------------- active_layer_depth.active_layer_depth(self, time, element) # ---------------------------------- # Cycle through terrestrial cohorts # ---------------------------------- check_Wet_NPG.check_Wet_NPG(self, element, time) check_Wet_LCP.check_Wet_LCP(self, element, time) check_Wet_CLC.check_Wet_CLC(self, element, time) check_Wet_FCP.check_Wet_FCP(self, element, time) check_Wet_HCP.check_Wet_HCP(self, element, time) # ---------------------------------- # Set pond/lake ice thickness depth # ---------------------------------- ice_thickness.ice_thickness(self, time, element) # ------------------------------ # Cycle through ponds and lakes # ------------------------------ check_Ponds.check_Ponds(self, element, time) check_Lakes.check_Lakes(self, element, time) # ------------------------------------------------- # Cohort Fraction Check (mass balance of cohorts) # ------------------------------------------------- cohort_check.cohort_check(self, element, time, cohort_start) if time == self.stop-1: if self.Simulation_area.lower() == 'barrow': cohorts.final_barrow(self) elif self.Simulation_area.lower() == 'tanana': cohorts.final_tanana(self) # ======================================================================== # END MAIN LOOP # ======================================================================== # ======================================================================== # OUTPUT RESULTS (if requested) # ======================================================================== # - - - - - - - - - # Fractional Areas # - - - - - - - - - Output_cohorts_by_year.Output_cohorts_by_year(self, time) # - - - - - - - - - - - - - # Dominant Fractional Area # - - - - - - - - - - - - - Output_cohorts_by_year.dominant_cohort(self) # Terrestrial_Control Output_cohorts_by_year.dominant_fractional_plot(self, time) # Terrestrial_Control # ================================= # OUTPUT ANIMATIONS (if requested) # ================================= # - - - - - - - - - - - - - - - # Fractional Area of Cohorts # - - - - - - - - - - - - - - - - Output_cohorts_by_year.write_Fractions_avi(self) Output_cohorts_by_year.write_Dominant_Cohort_avi(self) # Terrestrial_Control # ------------------- # Simulation End Time # ------------------- clock.finish(self) #=========================== # Output Simulation Results #=========================== if self.results_onscreen.lower() == 'yes': results.on_screen(self) if self.archive_simulation.lower() == 'yes': results.on_file(self) # ================ # Archive Results # ================ if self.archive_simulation.lower() == 'yes': #---------------------------------------------------------------------------------------------------------- # Create the tarfile #---------------------------------------------------------------------------------------------------------- self.archive_file =tarfile.open(self.control['Run_dir']+self.Output_directory+str('/Archive/')+ \ self.archive_time+str('_')+self.simulation_name+".tar.gz", mode='w:gz') #---------------------------------------------------------------------------------------------------------- archive.read_archive(self) archive.archive(self) print '----------------------------------------' print ' Simulation Complete ' print '----------------------------------------'