Dataset { Float32 T[T = 634]; Float32 len[len = 17]; String species[species = 10]; Float32 T_01[T_01 = 34]; Float32 T_02[T_02 = 47]; String port[port = 14]; Float32 T_03[T_03 = 330]; String loc[loc = 3]; Float32 T_04[T_04 = 694]; Float32 T_05[T_05 = 857]; Float32 T_06[T_06 = 312]; Structure { Structure { Grid { ARRAY: Float32 condition_factor[T = 634]; MAPS: Float32 T[T = 634]; } condition_factor; Grid { ARRAY: Float32 dist[T = 634][len = 17]; MAPS: Float32 T[T = 634]; Float32 len[len = 17]; } dist; Grid { ARRAY: Float32 nominal_catch[T = 634]; MAPS: Float32 T[T = 634]; } nominal_catch; } catch; Structure { Grid { ARRAY: Float32 daily_reprod_output[T = 634]; MAPS: Float32 T[T = 634]; } daily_reprod_output; Grid { ARRAY: Float32 egg_dvlp_time[T = 634]; MAPS: Float32 T[T = 634]; } egg_dvlp_time; Grid { ARRAY: Float32 est_mortality[T = 634]; MAPS: Float32 T[T = 634]; } est_mortality; Grid { ARRAY: Float32 map_standing_stock[T = 634]; MAPS: Float32 T[T = 634]; } map_standing_stock; Grid { ARRAY: Float32 mortality[T = 634]; MAPS: Float32 T[T = 634]; } mortality; Grid { ARRAY: Float32 parent_stock[T = 634]; MAPS: Float32 T[T = 634]; } parent_stock; Grid { ARRAY: Float32 sardine_biomass[T = 634]; MAPS: Float32 T[T = 634]; } sardine_biomass; } eggs; Structure { Structure { Grid { ARRAY: Float32 dist[T = 634][len = 17]; MAPS: Float32 T[T = 634]; Float32 len[len = 17]; } dist; } biomass; Grid { ARRAY: Float32 egg_production[T = 634]; MAPS: Float32 T[T = 634]; } egg_production; Structure { Grid { ARRAY: Float32 biomass[T = 634]; MAPS: Float32 T[T = 634]; } biomass; } mature_female; Structure { Grid { ARRAY: Float32 biomass[T = 634]; MAPS: Float32 T[T = 634]; } biomass; } mature_male_female; Grid { ARRAY: Float32 recruits[T = 634]; MAPS: Float32 T[T = 634]; } recruits; Structure { Grid { ARRAY: Float32 biomass[T = 634]; MAPS: Float32 T[T = 634]; } biomass; } total; } PeruI; Structure { Structure { Grid { ARRAY: Float32 dist[T = 634][len = 17]; MAPS: Float32 T[T = 634]; Float32 len[len = 17]; } dist; } biomass; Grid { ARRAY: Float32 egg_production[T = 634]; MAPS: Float32 T[T = 634]; } egg_production; Structure { Grid { ARRAY: Float32 biomass[T = 634]; MAPS: Float32 T[T = 634]; } biomass; } mature_female; Structure { Grid { ARRAY: Float32 biomass[T = 634]; MAPS: Float32 T[T = 634]; } biomass; } mature_male_female; Grid { ARRAY: Float32 recruits[T = 634]; MAPS: Float32 T[T = 634]; } recruits; Structure { Grid { ARRAY: Float32 biomass[T = 634]; MAPS: Float32 T[T = 634]; } biomass; } total; } PeruII; Structure { Grid { ARRAY: Float32 nominal_catch[T = 634]; MAPS: Float32 T[T = 634]; } nominal_catch; Structure { Grid { ARRAY: Float32 baseline_natural_mortality[T = 634]; MAPS: Float32 T[T = 634]; } baseline_natural_mortality; } PeruI; Structure { Grid { ARRAY: Float32 baseline_natural_mortality[T = 634]; MAPS: Float32 T[T = 634]; } baseline_natural_mortality; } PeruII; Structure { Grid { ARRAY: Float32 abundance[species = 10][T = 634]; MAPS: String species[species = 10]; Float32 T[T = 634]; } abundance; Structure { Grid { ARRAY: Float32 consumption[species = 10][T = 634]; MAPS: String species[species = 10]; Float32 T[T = 634]; } consumption; } anchovy; Grid { ARRAY: Float32 biomass[species = 10][T = 634]; MAPS: String species[species = 10]; Float32 T[T = 634]; } biomass; Grid { ARRAY: Float32 numbers[species = 10][T = 634]; MAPS: String species[species = 10]; Float32 T[T = 634]; } numbers; Structure { Grid { ARRAY: Float32 consumption[species = 10][T = 634]; MAPS: String species[species = 10]; Float32 T[T = 634]; } consumption; } total; } species; Grid { ARRAY: Float32 total_natural_mortality[T = 634]; MAPS: Float32 T[T = 634]; } total_natural_mortality; } predators; Structure { Structure { Grid { ARRAY: Float32 adult_stock[T_01 = 34]; MAPS: Float32 T_01[T_01 = 34]; } adult_stock; Grid { ARRAY: Float32 recruits[T_01 = 34]; MAPS: Float32 T_01[T_01 = 34]; } recruits; } mean; } yearly; } anchoveta; Structure { Structure { Grid { ARRAY: Float32 anchoveta[T_02 = 47]; MAPS: Float32 T_02[T_02 = 47]; } anchoveta; Grid { ARRAY: Float32 caballa[T_02 = 47]; MAPS: Float32 T_02[T_02 = 47]; } caballa; Structure { Grid { ARRAY: Float32 ports[port = 14][T_02 = 47]; MAPS: String port[port = 14]; Float32 T_02[T_02 = 47]; } ports; Grid { ARRAY: Float32 total[T_02 = 47]; MAPS: Float32 T_02[T_02 = 47]; } total; } human_consumption; Grid { ARRAY: Float32 jurel[T_02 = 47]; MAPS: Float32 T_02[T_02 = 47]; } jurel; Grid { ARRAY: Float32 sardina[T_02 = 47]; MAPS: Float32 T_02[T_02 = 47]; } sardina; } yearly; } catch; Structure { Structure { Grid { ARRAY: Float32 ind[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } ind; Grid { ARRAY: Float32 prices_Peru[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } prices_Peru; Grid { ARRAY: Float32 soyomeal_Brasil[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } soyomeal_Brasil; } FOB; Structure { Grid { ARRAY: Float32 fishmeal[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } fishmeal; Grid { ARRAY: Float32 soyameal[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } soyameal; } prices; Structure { Structure { Grid { ARRAY: Float32 num_boats[T_02 = 47]; MAPS: Float32 T_02[T_02 = 47]; } num_boats; Grid { ARRAY: Float32 num_plants[T_02 = 47]; MAPS: Float32 T_02[T_02 = 47]; } num_plants; Grid { ARRAY: Float32 ship_hold[T_02 = 47]; MAPS: Float32 T_02[T_02 = 47]; } ship_hold; Grid { ARRAY: Float32 total_capacity[T_02 = 47]; MAPS: Float32 T_02[T_02 = 47]; } total_capacity; } capacity; Structure { Grid { ARRAY: Float32 total[T_02 = 47]; MAPS: Float32 T_02[T_02 = 47]; } total; } exports; } yearly; } economics; Structure { Grid { ARRAY: Float32 absorbed_solar_radiation[T = 634]; MAPS: Float32 T[T = 634]; } absorbed_solar_radiation; Structure { Structure { Grid { ARRAY: Float32 primary_production[T = 634]; MAPS: Float32 T[T = 634]; } primary_production; } CDM; Structure { Structure { Grid { ARRAY: Float32 NO3[T = 634]; MAPS: Float32 T[T = 634]; } NO3; } CDM; Structure { Grid { ARRAY: Float32 NO3[T = 634]; MAPS: Float32 T[T = 634]; } NO3; } Conc*TrujUp_CDM; Structure { Grid { ARRAY: Float32 NO3[T = 634]; MAPS: Float32 T[T = 634]; } NO3; } Conc*TrujUp_VDM; Structure { Grid { ARRAY: Float32 NO3[T = 634]; MAPS: Float32 T[T = 634]; } NO3; } VDM; } flux_derived; Structure { Grid { ARRAY: Float32 primary_production[T = 634]; MAPS: Float32 T[T = 634]; } primary_production; } VDM; } coastal; Grid { ARRAY: Float32 lasker_events[T = 634]; MAPS: Float32 T[T = 634]; } lasker_events; Grid { ARRAY: Float32 mean_relat_cld_cvr[T = 634]; MAPS: Float32 T[T = 634]; } mean_relat_cld_cvr; Grid { ARRAY: Float32 NO3[T = 634][loc = 3]; MAPS: Float32 T[T = 634]; String loc[loc = 3]; } NO3; Structure { Structure { Grid { ARRAY: Float32 primary_production[T = 634]; MAPS: Float32 T[T = 634]; } primary_production; } CDM; Structure { Structure { Grid { ARRAY: Float32 NO3[T = 634]; MAPS: Float32 T[T = 634]; } NO3; } CDM; Structure { Grid { ARRAY: Float32 NO3[T = 634]; MAPS: Float32 T[T = 634]; } NO3; } Conc*Bakun_CDM; Structure { Grid { ARRAY: Float32 NO3[T = 634]; MAPS: Float32 T[T = 634]; } NO3; } Conc*Bakun_VDM; Structure { Grid { ARRAY: Float32 NO3[T = 634]; MAPS: Float32 T[T = 634]; } NO3; } VDM; } flux_derived; Structure { Grid { ARRAY: Float32 primary_production[T = 634]; MAPS: Float32 T[T = 634]; } primary_production; } VDM; } oceanic; Grid { ARRAY: Float32 primary_production[T = 634]; MAPS: Float32 T[T = 634]; } primary_production; Grid { ARRAY: Float32 rossby_radius[T = 634]; MAPS: Float32 T[T = 634]; } rossby_radius; Grid { ARRAY: Float32 sea_level[port = 14][T_04 = 694]; MAPS: String port[port = 14]; Float32 T_04[T_04 = 694]; } sea_level; Grid { ARRAY: Float32 SOI[T = 634]; MAPS: Float32 T[T = 634]; } SOI; Grid { ARRAY: Float32 sst[port = 14][T = 634]; MAPS: String port[port = 14]; Float32 T[T = 634]; } sst; Grid { ARRAY: Float32 thermocline_depth[T = 634]; MAPS: Float32 T[T = 634]; } thermocline_depth; Grid { ARRAY: Float32 turbulence[port = 14][T = 634]; MAPS: String port[port = 14]; Float32 T[T = 634]; } turbulence; Grid { ARRAY: Float32 upwelling[port = 14][T = 634]; MAPS: String port[port = 14]; Float32 T[T = 634]; } upwelling; Grid { ARRAY: Float32 velocity[T = 634]; MAPS: Float32 T[T = 634]; } velocity; Structure { Grid { ARRAY: Float32 sst[T_05 = 857]; MAPS: Float32 T_05[T_05 = 857]; } sst; } weekly; Grid { ARRAY: Float32 wind_velocity[port = 14][T = 634]; MAPS: String port[port = 14]; Float32 T[T = 634]; } wind_velocity; Grid { ARRAY: Float32 xbtpc1[T_06 = 312]; MAPS: Float32 T_06[T_06 = 312]; } xbtpc1; Grid { ARRAY: Float32 xbtpc2[T_06 = 312]; MAPS: Float32 T_06[T_06 = 312]; } xbtpc2; } environment; Structure { Structure { Structure { Grid { ARRAY: Float32 condition_factor[T = 634]; MAPS: Float32 T[T = 634]; } condition_factor; Grid { ARRAY: Float32 nominal_catch[T = 634]; MAPS: Float32 T[T = 634]; } nominal_catch; } catch; Structure { Grid { ARRAY: Float32 egg_production[T = 634]; MAPS: Float32 T[T = 634]; } egg_production; Grid { ARRAY: Float32 recruits[T = 634]; MAPS: Float32 T[T = 634]; } recruits; Structure { Grid { ARRAY: Float32 biomass[T = 634]; MAPS: Float32 T[T = 634]; } biomass; } total; } PeruII; } anchoveta; } Steve_filter; Structure { Structure { Grid { ARRAY: Float32 north[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } north; Grid { ARRAY: Float32 south[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } south; Grid { ARRAY: Float32 total[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } total; } Chile; Structure { Grid { ARRAY: Float32 Pesca[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } Pesca; Structure { Grid { ARRAY: Float32 Pesca[port = 14][T_03 = 330]; MAPS: String port[port = 14]; Float32 T_03[T_03 = 330]; } Pesca; Grid { ARRAY: Float32 Privates[port = 14][T_03 = 330]; MAPS: String port[port = 14]; Float32 T_03[T_03 = 330]; } Privates; Grid { ARRAY: Float32 total[port = 14][T_03 = 330]; MAPS: String port[port = 14]; Float32 T_03[T_03 = 330]; } total; } ports; Grid { ARRAY: Float32 Privates[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } Privates; Grid { ARRAY: Float32 total[T_03 = 330]; MAPS: Float32 T_03[T_03 = 330]; } total; } Peru; } weekly_fishing; } EPPF;