PRODUCT: RIVER.lab/Eros VERSION: 7.3.74M Floodos-Eros: 2d hydrodynamic code with advanced landscape evolution model, part of the RIVER.lab platform Copyright (c) 1998-2020 Philippe Davy, CNRS (Centre National de la Recherche Scientifique) PROGRAM: eros7.3.exe VERSION: 7.3.74.1be26006be970cb4e920b8870ce3e7dbc2bfb6d2 COMMIT : 2020-12-02 22:40:36 ARGUMENTS: help=1 //------------------------------------------------ // Program arguments //------------------------------------------------ [command] help=1 variables:[help = 1] //------------------------------------------------ // Set parameter values //------------------------------------------------ [VALID] help=1 //------------------------------------------------ EROS parameter list //------------------------------------------------ e.g., parameter = default_value arg = basement_erodability_fluvial = 0.000000 basement_erodability_hillslope = 0.000000 basement_grain_size_fluvial = -1.000000 # <double>: Basement grain size (used to calculate Shields parameters and critical stress basement_grain_size_hillslope = -1.000000 # <double>: Basement grain size (used to calculate Shields parameters and critical stress basement_shields_parameter_fluvial = -1.000000 # <double>: Basement Shields parameter basement_shields_parameter_hillslope = -1.000000 # <double>: Basement Shields parameter basement_threshold_fluvial = 0.000000 basement_threshold_hillslope = 0.000000 boundary = 0 boundary_sea = 0 boundary_sediment_equilibrium = 0 boundary_sediment_fluctuations = 0.000000 boundary_sediment_input = 0.000000 climate_frequency = 0.000000 climate_mean = 1.000000 climate_trend = 0.000000 climate_variation_amplitude = 0.000000 continue = -1 # <int>continue a simulation from a given stage 'continue=stage' dat = default_max = 20 default_min = -1 default_model = 0 default_op = 0 default_step = 1.000000 deposition_length_fluvial = 1.000000 deposition_length_hillslope = 1.000000 deposition_length_threshold_fluvial = 0.000000 deposition_length_threshold_hillslope = 0.000000 deposition_model = 1 diagonal_link = 0 diagonal_width_reduction = 0 diffusion_coefficient = 2.000000 dir = dir_input = erosion_limiter = 0.000000 erosion_limiter_coefficient = 10.000000 erosion_model = 3 fictious_area = 1.000000 file_climate = file_config = EROS file_erode = file_erode_sed = file_groundwater = file_hum = file_infiltration = file_manning = file_output = EROS file_rain = file_seallevel = file_sediment = file_threshold = file_threshold_sed = file_topo = file_uplift = file_water = flow_boundary = 0 # <int>Define how the water depth is calculated at the model boundaries: 0/constant, 1/topographic_slope/topo_slope, 2/free/same as the upstream cell flow_boundary_depth = -1.000000 flow_depth_constant = 1.000000 flow_exponent_of_river_width_fluvial = 0.000000 flow_exponent_of_river_width_hillslope = 0.000000 flow_exponent_of_transfert_length_fluvial = 0.000000 flow_exponent_of_transfert_length_hillslope = 0.000000 flow_inertia_coefficient = 0.000000 flow_model = 1 flow_width_fluvial = 0.000000 flow_width_hillslope = 0.000000 flux = flux_area = -1.000000 flux_averaging = 20 flux_scaling = 2 friction_coefficient = 0.000000 friction_model = 2 gravity_slope = 0.000000 groundwater_diffusivity = 10000000.000000 groundwater_epsilon = 0.000100 groundwater_infiltration = 0.000000 groundwater_porosity = 0.100000 groundwater_tide = -9999.000000 help = 1 hydraulic_model = 0 infiltration_rate = 0.000000 inflow = -1.000000 # The total inflow provided to the model according to a probability given by the rainfall map injected_particle_number = 0 input_mode = 0 # discontinued input_name = EROS isostatic_factor = 0.000000 isostatic_length = 1.000000 isostatic_offset = 0.000000 landslide_cohesion_(m) = 0.000000 # <double>cohesion in meter landslide_dynamic_slope = 0.150000 # <double>dynamic friction slope landslide_friction_angle = 0.523600 # <double>friction angle in radian landslide_runout_diffusion_coefficient = 1.000000 # <double>Coefficient D that defines the probability P of landslide runout to move in one or another direction (P is proportional to the local slope to the power D) landsliding = 0 # <int>a flag to know if landsliding is on (1:on, 0:off) lateral_deposition_coefficient_fluvial = 0.000000 lateral_deposition_coefficient_hillslope = 0.000000 lateral_deposition_model = 1 lateral_erosion_coefficient_fluvial = 0.000000 lateral_erosion_coefficient_hillslope = 0.000000 lateral_erosion_function = 0 lateral_erosion_inbend = 1.000000 lateral_erosion_max_fluvial = 10000000000.000000 lateral_erosion_max_hillslope = 10000000000.000000 lateral_erosion_model = 0 lateral_erosion_outbend = 1.000000 lateral_erosion_straight = 1.000000 lateral_neighbor_number = 1 max_diffusivity_coef = 0.250000 maximum_transfer_length_fluvial = 340282346638528859811704183484516925440.000000 maximum_transfer_length_hillslope = 340282346638528859811704183484516925440.000000 minimum_transfer_length_fluvial = 0.000000 minimum_transfer_length_hillslope = 0.000000 mode_of_process_change_with_rain = -1 model = 0 nowrite = 1048599 particle_initial_distance = 0 particle_injection_final_time = 0.000000 particle_injection_starting_time = 0.000000 particle_trapping_distance = 3 pause = 0 periodic = 0 point = poisson_coefficient = 4 power_exponent_for_discharge_fluvial = 1.000000 power_exponent_for_discharge_hillslope = 1.000000 power_exponent_for_slope_fluvial = 1.000000 power_exponent_for_slope_hillslope = 1.000000 precipiton_lakes = -1 precipiton_steps_maximum = -1 precipiton_volume_maximum = 2.000000 print_mass_balance = 0 print_tu = 1 rainfall_multiplier = 1.000000 # The rainfall is the rain quantity per unit surface. It is the product of the rain map and of the rainfall multiplier recharge = 0 sea_level = -9999.000000 sediment_density = 2000.000000 sediment_erodability_fluvial = 0.000000 sediment_erodability_hillslope = 0.000000 sediment_grain_size_fluvial = -1.000000 # <double>: Sediment grain size (used to calculate Shields parameters and critical stress sediment_grain_size_hillslope = -1.000000 # <double>: Sediment grain size (used to calculate Shields parameters and critical stress sediment_overefficiency_fluvial = -1.000000 sediment_overefficiency_hillslope = -1.000000 sediment_shields_parameter_fluvial = -1.000000 # <double>: Sediment Shields parameter sediment_shields_parameter_hillslope = -1.000000 # <double>: Sediment Shields parameter sediment_stress_exponent_fluvial = 1.000000 sediment_stress_exponent_hillslope = 1.000000 sediment_threshold_fluvial = 0.000000 sediment_threshold_hillslope = 0.000000 seed = -1 semiperiodic = 0 shields_critical_fluvial = 0.047000 shields_critical_hillslope = 0.047000 slope_erosion_model = 1 smooth_coef = 0.980000 smooth_function = 0 splash_coefficient = 0.000000 stage = start_from = -1 # <int>start a previous simulation from a given stage start_from_scratch = -1 stationary_max = 5 stationary_mode = 0 stationary_volume = 0.000000 strike-slip_line = 0.000000 strike-slip_rate = 0.000000 strike-slip_sense = 0 tectonic_uplift_rate = 0.000000 thrust_angle_(in_degrees) = 0.000000 thrust_length = 0.000000 thrust_position = 0.000000 thrust_sense = 0 thrust_width = 0.000000 thrusting_rate = 0.000000 thrusting_uplift = 0.000000 time_begin = 0.000000 # <double>starting time (excluding the init phase) time_draw = -1.000000 time_end = -1.000000 # <double>final time time_erosion_multiplier = 1.000000 # <double>multiplying factor for erosion rates. Equivalent to consider an "erosion time" larger than the hydrodynamic time time_init = 0.000000 time_init_begin = 0.000000 # <double>time step or precipiton volume at the beginning of the init phase time_init_end = 0.000000 # <double>time step or precipiton volume to reach at the end of the init phase time_init_op = 0 # <op>the way in which the time step or precipiton volume is changed between two successive stages (+ or * time_init_step = 0.000000 # <double>change in time step or precipiton volume after each stage of the init phase time_init_tu = 1 # <int>duration of each phase of the init phase in TU units time_step = -1.000000 # <double>time step or precipiton volume during calculation - time:step=XXX:option, the option can be time, volume or TU time_step_max = -1.000000 # <double>largest time step or precipiton volume during calculation time_step_min = -1.000000 # <double>smallest time step or precipiton volume during calculation time_unit = 1.000000 # <double>unit for time scale. #1 if the time scale of model parameters is different from that recorder topographic_noise = 0.000000 trace_begin = -1.000000 trace_end = -1.000000 trace_step = -1.000000 transition_area = -1.000000 transition_flux = -1.000000 tu_coefficient = 1.000000 undersea_coefficient = 0.000000 update_epsilon = 0.000000 wet_season_duration = 1.000000 wet_season_rainfall = 1.000000 wet_season_recurrence_time = 0.000000 where_is_tectonic_uplift = 0 write = 1048599 writing_mode = 0 Hope you were happy with Eros D:\SynologyDrive\erosmatlabinterface\bin>