######################################################## # routines to set up weather tiles # Thorsten Renk, June 2011 ######################################################## # function purpose # # tile_start to execute jobs common for all tiles on startup # tile_finished to execute jobs common for all tiles when tile creation is done # set_NN_tile to set a weather tile of type NN # create_NN to create the cloud configuration NN # adjust_p to make sure pressure variation cannot exceed limits between tiles # calc_geo to get local Cartesian geometry for latitude conversion # get_lat to get latitude from Cartesian coordinates # get_lon to get longitude from Cartesian coordinates #################################### # tile setup calls #################################### var tile_start = func { # set thread lock if (local_weather.thread_flag == 1){setprop(lw~"tmp/thread-status","computing");} # set the tile code var current_code = getprop(lw~"tiles/code"); var dir_index = getprop(lw~"tiles/tmp/dir-index"); props.globals.getNode(lw~"tiles").getChild("tile",dir_index).getNode("code").setValue(current_code); #print(current_code, getprop(lw~"tiles/tmp/code")); if (current_code != getprop(lw~"tiles/tmp/code")) {weather_tiles.rnd_store = rand();} # generate a handling array for models var array = []; append(weather_tile_management.modelArrays,array); } var tile_finished = func { var current_code = getprop(lw~"tiles/code"); setprop(lw~"clouds/placement-index",0); setsize(elat,0); setsize(elon,0); setsize(erad,0); var dir_index = getprop(lw~"tiles/tmp/dir-index"); #props.globals.getNode(lw~"tiles").getChild("tile",dir_index).getNode("code").setValue(current_code); local_weather.assemble_effect_array(); if (local_weather.debug_output_flag == 1) {print("Finished setting up tile type ",current_code, " in direction ",dir_index);} if (local_weather.thread_flag == 1) {setprop(lw~"tmp/thread-status","placing");} else # without worker threads, tile generation is complete at this point {props.globals.getNode(lw~"tiles").getChild("tile",dir_index).getNode("generated-flag").setValue(2);} } #################################### # test tile #################################### var set_4_8_stratus_tile = func { setprop(lw~"tiles/code","test"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # first weather info for tile center (lat, lon, visibility, temperature, dew point, pressure) local_weather.set_weather_station(blat, blon, alt_offset, 30000.0, 14.0, 12.0, 29.78); alt_offset = 0.0; #var strength = 0.5; #local_weather.create_cumosys(blat,blon, 3000.0, get_n(strength), 20000.0); #create_2_8_altocumulus_streaks(blat, blon, 12000+alt_offset, alpha) ; #create_2_8_altocumulus_streaks(blat, blon, 12000+alt_offset, alpha) ; #create_6_8_stratus(blat, blon, 3000+alt_offset, alpha) ; #create_4_8_tstratus_patches(blat, blon, 5000+alt_offset, alpha) ; #create_4_8_sstratus_patches(blat, blon, 5000+alt_offset, alpha) ; #create_4_8_cirrostratus_patches(blat, blon, 5000+alt_offset, alpha) ; #create_4_8_cirrocumulus_streaks(blat, blon, 10000.0 + alt_offset, alpha); #create_4_8_alttstratus_streaks(blat, blon, 5000+alt_offset, alpha) ; #create_2_8_cirrocumulus_patches(blat, blon, 13000+alt_offset, alpha) ; #create_8_8_nimbus_rain(blat, blon, 3000+alt_offset, alpha, 0.3) ; #create_8_8_tstratus(blat, blon, 5000+alt_offset, alpha); #create_8_8_cirrostratus(blat, blon, 5000+alt_offset, alpha); create_thunderstorm_scenario (blat, blon, 3000.0, alpha); #create_big_thunderstorm (blat, blon, 3000.0, alpha); #create_4_8_altocumulus_perlucidus(blat, blon, 5000+alt_offset, alpha) ; #create_detailed_stratocumulus_bank(blat, blon, 4000+alt_offset,alpha); #store convective altitude and strength local_weather.set_atmosphere_ipoint(blat, blon, 45000.0, 15000.0, 45000.0, 0.0, 15000.0, 17000.0, 0.8, 12000.0, 17000.0); append(weather_dynamics.tile_convective_altitude,3000.0); append(weather_dynamics.tile_convective_strength,0.0); tile_finished(); } #################################### # high pressure core #################################### var set_high_pressure_core_tile = func { setprop(lw~"tiles/code","high_pressure_core"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 25000.0 + rand() * 10000.0; var T = 20.0 + rand() * 10.0; var spread = 14.0 + 8.0 * rand(); var D = T - spread; var p = 1025.0 + rand() * 6.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # and set them at the tile center local_weather.set_weather_station(blat, blon, alt_offset, vis, T, D, p * hp_to_inhg); var alt = spread * 400; var strength = 0.0; var rn = rand(); if (rand() < small_scale_persistence) {rn = rnd_store;} else {rnd_store = rn;} #rn = 0.1; if (rn > 0.8) { # cloud scenario 1: weak cumulus development and blue thermals strength = rand() * 0.05; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); # generate a few blue thermals if (local_weather.generate_thermal_lift_flag !=0) { local_weather.generate_thermal_lift_flag = 3; strength = rand() * 0.4; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); local_weather.generate_thermal_lift_flag = 2; } # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, 25000.0, 30000.0, 0.9, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.6) { # cloud scenario 2: some Cirrocumulus patches strength = rand() * 0.03; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_2_8_cirrocumulus(blat, blon, alt + alt_offset + 5000.0, alpha); create_2_8_cirrus(blat, blon, alt + alt_offset + 35000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.1, alt+alt_offset +30000.0, alt+alt_offset + 35000.0, 0.9, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.4) { # cloud scenario 3: Cirrostratus undulatus over weak cumulus strength = rand() * 0.03; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_4_8_cirrostratus_undulatus(blat, blon, alt + alt_offset + 32000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.15, alt+alt_offset +28000.0, alt+alt_offset + 32000.0, 0.9, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.2) { # cloud scenario 4: Cirrostratus undulatus streak strength = rand() * 0.03; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_1_8_cirrostratus_undulatus(blat, blon, alt + alt_offset + 32000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.15, alt+alt_offset +28000.0, alt+alt_offset + 32000.0, 0.9, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.0) { # cloud scenario 5: Cirrus create_2_8_cirrus(blat, blon, alt + alt_offset + 35000.0, alpha); create_1_8_cirrostratus_undulatus(blat, blon, alt + alt_offset + 28000.0, alpha); create_1_8_cirrostratus_undulatus(blat, blon, alt + alt_offset + 28000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +28000.0, alt+alt_offset + 33000.0, 0.9, alt+alt_offset, alt+alt_offset + 2500.0); } # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # high pressure #################################### var set_high_pressure_tile = func { setprop(lw~"tiles/code","high_pressure"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 20000.0 + rand() * 10000.0; var T = 15.0 + rand() * 10.0; var spread = 10.0 + 4.0 * rand(); var D = T - spread; var p = 1019.0 + rand() * 6.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # and set them at the tile center local_weather.set_weather_station(blat, blon, alt_offset, vis, T, D, p * hp_to_inhg); var alt = spread * 400; var strength = 0.0; # print("alt: ",alt, "spread: ", spread, "offset: ", alt_offset); var rn = rand(); if (rand() < small_scale_persistence) {rn = rnd_store;} else {rnd_store = rn;} # rn = 0.1; if (rn > 0.8) { # cloud scenario 1: possible Cirrus over Cumulus strength = 0.2 + rand() * 0.4; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); # one or two Cirrus clouds x = 2000.0 + rand() * 16000.0; y = 2.0 * (rand()-0.5) * 18000; var path = local_weather.select_cloud_model("Cirrus", "small"); compat_layer.create_cloud(path, blat + get_lat(x,y,phi), blon+get_lon(x,y,phi), alt + alt_offset + 25000.0 + rand() * 5000.0,alpha); if (rand() > 0.5) { x = -2000.0 - rand() * 16000.0; y = 2.0 * (rand()-0.5) * 18000; var path = local_weather.select_cloud_model("Cirrus", "small"); compat_layer.create_cloud(path, blat + get_lat(x,y,phi), blon+get_lon(x,y,phi), alt + alt_offset +25000.0 + rand() * 5000.0,alpha); } # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +28000.0, alt+alt_offset + 30000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.6) { # cloud scenario 2: Cirrostratus over weak Cumulus strength = 0.2 + rand() * 0.2; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_2_8_cirrostratus(blat, blon, alt+alt_offset+25000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.2, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.4) { # cloud scenario 3: Cirrocumulus sheet over Cumulus strength = 0.2 + rand() * 0.2; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); x = 2.0 * (rand()-0.5) * 5000; y = 2.0 * (rand()-0.5) * 5000; var path = local_weather.select_cloud_model("Cirrocumulus", "large"); compat_layer.create_cloud(path, blat + get_lat(x,y,phi), blon+get_lon(x,y,phi), alt + alt_offset +24000,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 24000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.2) { # cloud scenario 4: Cirrostratus undulatus over weak Cumulus strength = 0.15 + rand() * 0.15; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_4_8_cirrostratus_undulatus(blat, blon, alt + alt_offset + 25000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.15, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.0) { # cloud scenario 5: some scattered Altocumuli over Cumulus strength = 0.25 + rand() * 0.1; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_1_8_altocumulus_scattered(blat, blon, alt+alt_offset+10000.0, alpha); create_1_8_cirrostratus_undulatus(blat, blon, alt + alt_offset + 25000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # high pressure border #################################### var set_high_pressure_border_tile = func { setprop(lw~"tiles/code","high_pressure_border"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 15000.0 + rand() * 7000.0; var T = 12.0 + rand() * 10.0; var spread = 7.0 + 4.0 * rand(); var D = T - spread; var p = 1013.0 + rand() * 6.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # and set them at the tile center local_weather.set_weather_station(blat, blon, alt_offset, vis, T, D, p * hp_to_inhg); # now a random selection of different possible cloud configuration scenarios var alt = spread * 400; var strength = 0.0; var rn = rand(); if (rand() < small_scale_persistence) {rn = rnd_store;} else {rnd_store = rn;} if (rn > 0.888) { # cloud scenario 1: Altocumulus patch over weak Cumulus strength = 0.1 + rand() * 0.1; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); x = 2.0 * (rand()-0.5) * 5000; y = 2.0 * (rand()-0.5) * 5000; local_weather.create_streak("Altocumulus",blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 12000.0+alt+alt_offset,1500.0,30,1000.0,0.2,1200.0,30,1000.0,0.2,1200.0,alpha ,1.0); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.777) { # cloud scenario 2: Altocumulus streaks strength = 0.15 + rand() * 0.2; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); x = 2.0 * (rand()-0.5) * 10000; y = 2.0 * (rand()-0.5) * 10000; local_weather.create_streak("Altocumulus",blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 12000.0+alt+alt_offset,1500.0,25,700.0,0.2,800.0,10,700.0,0.2,800.0,alpha ,1.4); x = 2.0 * (rand()-0.5) * 10000; y = 2.0 * (rand()-0.5) * 10000; local_weather.create_streak("Altocumulus",blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 12000.0+alt+alt_offset,1500.0,22,750.0,0.2,1000.0,8,750.0,0.2,1000.0,alpha ,1.1); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.666) { # cloud scenario 3: Cirrus strength = 0.1 + rand() * 0.1; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_2_8_cirrus(blat, blon, alt + 28000.0 + alt_offset, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 22000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.555) { # cloud scenario 4: Cumulonimbus banks strength = 0.7 + rand() * 0.3; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); for (var i = 0; i < 3; i = i + 1) { x = 2.0 * (rand()-0.5) * 16000; y = 2.0 * (rand()-0.5) * 16000; create_cloud_bank("Cumulonimbus", blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset, 1600.0, 800.0, 3000.0, 9, alpha); } # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.444) { # cloud scenario 5: scattered Stratus strength = 0.4 + rand() * 0.2; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); var size_offset = 0.5 * m_to_ft * local_weather.cloud_vertical_size_map["Stratus_structured"]; local_weather.create_streak("Stratus (structured)",blat, blon, alt+6000.0+alt_offset+size_offset,1000.0,18,0.0,0.3,20000.0,18,0.0,0.3,20000.0,0.0,1.0); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.2, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.333) { # cloud scenario 6: Cirrocumulus sheets strength = 0.2 + rand() * 0.2; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); for (var i = 0; i < 2; i = i + 1) { x = 2.0 * (rand()-0.5) * 10000; y = -6000 + i * 12000 + 2.0 * (rand()-0.5) * 1000; var beta = rand() * 90; var alt_variation = rand() * 2000; var path = local_weather.select_cloud_model("Cirrocumulus", "large"); compat_layer.create_cloud(path, blat + get_lat(x,y,phi), blon+get_lon(x,y,phi), alt + alt_offset +20000+ alt_variation,alpha+ beta); } # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.85, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.222) { # cloud scenario 7: Thin Cirrocumulus sheets over weak Cumulus strength = 0.05 + rand() * 0.1; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_4_8_cirrocumulus_streaks(blat, blon, alt + 6000.0 + alt_offset, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.05, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.111) { # cloud scenario 8: Altocumulus perlucidus create_4_8_altocumulus_perlucidus(blat, blon, alt + 10000.0 + alt_offset, alpha); create_2_8_cirrus(blat, blon, alt + 30000.0 + alt_offset, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.25, alt+alt_offset +26000.0, alt+alt_offset + 30000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.0) { # cloud scenario 9: Cumulus, Altocumulus and Cirrus strength = 0.3 + rand() * 0.15; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_1_8_altocumulus_scattered(blat, blon, alt + 12000.0 + alt_offset, alpha); create_2_8_altocumulus_streaks(blat, blon, alt + 12000.0 + alt_offset, alpha); create_2_8_cirrus(blat, blon, alt + 30000.0 + alt_offset, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +26000.0, alt+alt_offset + 30000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # low pressure border #################################### var set_low_pressure_border_tile = func { setprop(lw~"tiles/code","low_pressure_border"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 8000.0 + rand() * 8000.0; var T = 10.0 + rand() * 10.0; var spread = 6.0 + 2.0 * rand(); var D = T - spread; var p = 1007.0 + rand() * 6.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # and set them at the tile center local_weather.set_weather_station(blat, blon, alt_offset, vis, T, D, p * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0; var strength = 0.0; # bias Cumulus clouds towards larger sizes due to lots of water vapour local_weather.convective_size_bias = 0.2 + rand() * 0.2; # now a random selection of different possible cloud configuration scenarios var rn = rand(); if (rand() < small_scale_persistence) {rn = rnd_store;} else {rnd_store = rn;} if (rn > 0.857) { # cloud scenario 1: low Stratocumulus, thin streaks above strength = 0.05 + rand() * 0.1; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_detailed_stratocumulus_bank(blat, blon, alt+alt_offset,alpha); create_4_8_alttstratus_streaks(blat, blon, alt+alt_offset+4000.0,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.75, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.714) { # cloud scenario 2: weak Cumulus, Stratus undulatus above strength = 0.2 + rand() * 0.2; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_6_8_tstratus_undulatus(blat, blon, alt+alt_offset+4000.0,alpha); create_2_8_alttstratus(blat, blon, alt+alt_offset+7000.0,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.571) { # cloud scenario 3: Stratocumulus banks with patches above create_detailed_stratocumulus_bank(blat, blon, alt+alt_offset,alpha); create_detailed_small_stratocumulus_bank(blat, blon, alt+alt_offset,alpha); create_4_8_alttstratus_patches(blat, blon, alt+alt_offset+4000.0,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.7, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.428) { # cloud scenario 4: structured Stratus alt = alt + local_weather.cloud_vertical_size_map["Stratus"] * 0.5 * m_to_ft; create_4_8_sstratus_patches(blat, blon, alt+alt_offset,alpha); create_2_8_alttstratus(blat, blon, alt+alt_offset+7000.0,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.25, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.7, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.285) { # cloud scenario 5: Stratus blending with Cumulus with Cirrocumulus above strength = 0.1 + rand() * 0.1; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_4_8_tstratus_patches(blat, blon, alt+alt_offset,alpha); create_4_8_cirrocumulus_undulatus(blat, blon, alt+alt_offset + 12000.0,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.15, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.75, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.142) { # cloud scenario 6: small Stratocumulus banks create_detailed_small_stratocumulus_bank(blat, blon, alt+alt_offset,alpha); create_detailed_small_stratocumulus_bank(blat, blon, alt+alt_offset,alpha); create_4_8_tstratus_patches(blat, blon, alt+alt_offset,alpha); create_2_8_cirrostratus(blat, blon, alt+alt_offset + 25000.0,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.3, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.75, alt+alt_offset, alt+alt_offset + 2500.0); } else { # cloud scenario 7: blended structured and unstructured Stratiform clouds create_4_8_tstratus_patches(blat, blon, alt+alt_offset,alpha); create_4_8_sstratus_patches(blat, blon, alt+alt_offset,alpha); create_2_8_cirrostratus(blat, blon, alt+alt_offset + 25000.0,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 15000.0, 0.2, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.75, alt+alt_offset, alt+alt_offset + 2500.0); } # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # low pressure #################################### var set_low_pressure_tile = func { setprop(lw~"tiles/code","low_pressure"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; if (local_weather.presampling_flag == 0) {var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft");} else {var alt_offset = getprop(lw~"tmp/tile-alt-layered-ft");} # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 8000.0 + rand() * 5000.0; var T = 5.0 + rand() * 10.0; var spread = 5.0 + 2.0 * rand(); var D = T - spread; var p = 1001.0 + rand() * 6.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # and set them at the tile center local_weather.set_weather_station(blat, blon, alt_offset, vis, T, D, p * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0; var strength = 0.0; var rn = rand(); if (rand() < small_scale_persistence) {rn = rnd_store;} else {rnd_store = rn;} #rn = 0.1; if (rn > 0.8) { # cloud scenario 1: two patches of Nimbostratus with precipitation # overhead broken stratus layers # cloud count 1050 x = 2.0 * (rand()-0.5) * 11000.0; y = 2.0 * (rand()-0.5) * 11000.0; var beta = rand() * 360.0; var alt_eff = alt; if (local_weather.hardcoded_clouds_flag == 1) {alt_eff = alt_eff - 3000.0;} local_weather.create_layer("Nimbus", blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), alt_eff+alt_offset, 500.0, 12000.0, 7000.0, beta, 1.0, 0.2, 1, 1.0); local_weather.create_effect_volume(2, blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 10000.0, 6000.0, beta, 0.0, alt + alt_offset, 5000.0, 0.3, -1, -1, -1,0,-1 ); local_weather.create_effect_volume(2, blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 9000.0, 5000.0, beta, 0.0, alt+alt_offset-300.0, 1500.0, 0.5, -1, -1, -1,0,-1 ); x = 2.0 * (rand()-0.5) * 11000.0; y = 2.0 * (rand()-0.5) * 11000.0; var beta = rand() * 360.0; local_weather.create_layer("Nimbus", blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), alt_eff+alt_offset, 500.0, 10000.0, 6000.0, beta, 1.0, 0.2, 1, 1.0); local_weather.create_effect_volume(2, blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 9000.0, 5000.0, beta, 0.0, alt + alt_offset, 5000.0, 0.3, -1, -1, -1,0 ,-1); local_weather.create_effect_volume(2, blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 8000.0, 4000.0, beta, 0.0, alt+alt_offset-300.0, 1500.0, 0.5, -1, -1, -1,0,-1 ); create_4_8_sstratus_undulatus(blat, blon, alt+alt_offset +3000.0, alpha); create_2_8_tstratus(blat, blon, alt+alt_offset +6000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 17000.0, alt+alt_offset, vis + 22000.0, 0.2, alt+alt_offset +15000.0, alt+alt_offset + 20000.0, 0.7, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn >0.6) { # cloud scenario 2: 8/8 Stratus with light precipitation # above broken cover # cloud count 1180 alt = alt + local_weather.cloud_vertical_size_map["Stratus"] * 0.5 * m_to_ft; create_8_8_stratus(blat, blon, alt+alt_offset,alpha); local_weather.create_effect_volume(3, blat, blon, 18000.0, 18000.0, 0.0, 0.0, 1800.0, 8000.0, -1, -1, -1, -1, 0,-1); local_weather.create_effect_volume(3, blat, blon, 14000.0, 14000.0, 0.0, 0.0, 1500.0, 6000.0, 0.1, -1, -1, -1,0,-1 ); create_2_8_sstratus(blat, blon, alt+alt_offset+3000,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 17000.0, alt+alt_offset, vis + 25000.0, 0.3, alt+alt_offset +15000.0, alt+alt_offset + 20000.0, 0.6, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn >0.4) { # cloud scenario 3: multiple broken layers # cloud count 1350 alt = alt + local_weather.cloud_vertical_size_map["Stratus"] * 0.5 * m_to_ft; create_4_8_stratus(blat, blon, alt+alt_offset,alpha); create_4_8_stratus_patches(blat, blon, alt+alt_offset+3000,alpha); create_4_8_sstratus_undulatus(blat, blon, alt+alt_offset+6000,alpha); create_2_8_tstratus(blat, blon, alt+alt_offset+8000,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 17000.0, alt+alt_offset, vis + 25000.0, 0.35, alt+alt_offset +10000.0, alt+alt_offset + 20000.0, 0.65, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn >0.2) { # cloud scenario 4: a low 6/8 layer and some clouds above # cloud count 650 alt = alt + local_weather.cloud_vertical_size_map["Stratus"] * 0.5 * m_to_ft; create_6_8_stratus(blat, blon, alt+alt_offset,alpha); create_2_8_sstratus(blat, blon, alt+alt_offset+6000,alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 15000.0, alt+alt_offset, vis + 24000.0, 0.2, alt+alt_offset +15000.0, alt+alt_offset + 22000.0, 0.6, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn >0.0) { # cloud scenario 5: a low 8/8 layer without rain alt = alt + local_weather.cloud_vertical_size_map["Nimbus"] * 0.5 * m_to_ft; create_8_8_nimbus_rain(blat, blon, alt+alt_offset, alpha,0.0); if (rand() > 0.5) { create_2_8_cirrus(blat, blon, alt+alt_offset + 28000.0,alpha); } # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 15000.0, alt+alt_offset, vis + 24000.0, 0.05, alt+alt_offset +5000.0, alt+alt_offset + 8000.0, 0.55, alt+alt_offset, alt+alt_offset + 2500.0); } # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # low pressure core #################################### var set_low_pressure_core_tile = func { setprop(lw~"tiles/code","low_pressure_core"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; if (local_weather.presampling_flag == 0) {var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft");} else {var alt_offset = getprop(lw~"tmp/tile-alt-layered-ft");} # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 5000.0 + rand() * 5000.0; var T = 3.0 + rand() * 7.0; var spread = 4.5 + 1.0 * rand(); var D = T - spread; var p = 995.0 + rand() * 6.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # and set them at the tile center local_weather.set_weather_station(blat, blon, alt_offset, vis, T, D, p * hp_to_inhg); # set a closed Nimbostratus layer var alt = spread * 400.0; var strength = 0.0; #var alt = 3000.0; create_8_8_nimbus_rain(blat, blon, alt+alt_offset, alpha,0.4 + rand()*0.2); # and some broken Stratus cover above var rn = rand(); if (rand() < small_scale_persistence) {rn = rnd_store;} else {rnd_store = rn;} if (rn > 0.5){create_4_8_stratus_patches(blat, blon, alt+alt_offset+3000.0, alpha);} else {create_4_8_stratus(blat, blon, alt+alt_offset+3000.0, alpha);} local_weather.set_atmosphere_ipoint(blat, blon, vis + 20000.0, alt+alt_offset, vis + 25000.0, 0.0, alt+alt_offset +15000.0, alt+alt_offset + 22000.0, 0.6, alt+alt_offset, alt+alt_offset + 3000.0); # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # cold sector #################################### var set_cold_sector_tile = func { setprop(lw~"tiles/code","cold_sector"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 40000.0 + rand() * 15000.0; var T = 8.0 + rand() * 8.0; var spread = 7.0 + 3.0 * rand(); var D = T - spread; var p = 1005.0 + rand() * 10.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # and set them at the tile center local_weather.set_weather_station(blat, blon, alt_offset, vis, T, D, p * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0; var strength = 0.0; var rn = rand(); if (rand() < small_scale_persistence) {rn = rnd_store;} else {rnd_store = rn;} #rn = 0.1; if (rn > 0.5) { # cloud scenario 1: strong Cumulus development strength = 0.8 + rand() * 0.2; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 8000.0, alt+alt_offset, vis + 18000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.75, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.0) { # cloud scenario 2: Cirrocumulus sheets over Cumulus strength = 0.6 + rand() * 0.2; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); for (var i = 0; i < 2; i = i + 1) { x = 2.0 * (rand()-0.5) * 10000; y = -6000 + i * 12000 + 2.0 * (rand()-0.5) * 1000; var beta = rand() * 90; var alt_variation = rand() * 2000; var path = local_weather.select_cloud_model("Cirrocumulus", "large"); compat_layer.create_cloud(path, blat + get_lat(x,y,phi), blon+get_lon(x,y,phi), alt + alt_offset +20000+ alt_variation,alpha+ beta); } # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 8000.0, alt+alt_offset, vis + 18000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.75, alt+alt_offset, alt+alt_offset + 2500.0); } #local_weather.create_effect_volume(3, blat, blon, 20000.0, 7000.0, alpha, 0.0, 80000.0, -1, -1, -1, -1, 15.0, -3,-1); # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # Warm sector #################################### var set_warm_sector_tile = func { setprop(lw~"tiles/code","warm_sector"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 8000.0 + rand() * 5000.0; var T = 16.0 + rand() * 10.0; var spread = 6.0 + 3.0 * rand(); var D = T - spread; var p = 1005.0 + rand() * 10.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # and set them at the tile center local_weather.set_weather_station(blat, blon, alt_offset, vis, T, D, p * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0; var strength = 0.0; # bias Cumulus clouds towards larger sizes due to lots of water vapour local_weather.convective_size_bias = 0.1 + rand() * 0.1; var rn = rand(); if (rand() < small_scale_persistence) {rn = rnd_store;} else {rnd_store = rn;} if (rn > 0.8) { # cloud scenario 1: weak Cumulus development, some Cirrostratus strength = 0.3 + rand() * 0.2; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); create_4_8_cirrostratus_patches(blat, blon, alt+alt_offset+25000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 1000.0, alt+alt_offset, vis + 3000.0, 0.3, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.75, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.6) { # cloud scenario 2: weak Cumulus development under Altostratus streaks strength = 0.1 + rand() * 0.1; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); var size_offset = 0.5 * m_to_ft * local_weather.cloud_vertical_size_map["Stratus_structured"]; create_2_8_sstratus_streak(blat, blon, alt+alt_offset + size_offset + 2000.0, alpha); create_2_8_sstratus_streak(blat, blon, alt+alt_offset + size_offset + 4000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 1000.0, alt+alt_offset, vis + 3000.0, 0.2, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.75, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.4) { # cloud scenario 3: Cirrocumulus bank strength = 0.05 + rand() * 0.05; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); var size_offset = 0.5 * m_to_ft * local_weather.cloud_vertical_size_map["Cirrocumulus"]; create_4_8_cirrocumulus_bank(blat, blon, alt+alt_offset + size_offset + 7000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 1000.0, alt+alt_offset, vis + 3000.0, 0.35, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.75, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.2) { # cloud scenario 4: Cirrocumulus undulatus strength = 0.05 + rand() * 0.05; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); var size_offset = 0.5 * m_to_ft * local_weather.cloud_vertical_size_map["Cirrocumulus"]; create_4_8_cirrocumulus_undulatus(blat, blon, alt+alt_offset + size_offset + 6000.0, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 1000.0, alt+alt_offset, vis + 3000.0, 0.2, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.72, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.0) { # cloud scenario 5: weak Cumulus development under scattered Altostratus strength = 0.15 + rand() * 0.15; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); var size_offset = 0.5 * m_to_ft * local_weather.cloud_vertical_size_map["Stratus_structured"]; local_weather.create_streak("Stratus (structured)",blat, blon, alt+4000.0+alt_offset+size_offset,1000.0,14,0.0,0.3,20000.0,14,0.0,0.3,20000.0,0.0,1.0); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 2000.0, alt+alt_offset, vis + 4000.0, 0.15, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.73, alt+alt_offset, alt+alt_offset + 2500.0); } # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # Tropical weather #################################### var set_tropical_weather_tile = func { setprop(lw~"tiles/code","tropical_weather"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var sec_to_rad = 2.0 * math.pi/86400; # conversion factor for sinusoidal dependence on daytime # get the local time of the day in seconds var t = getprop("sim/time/utc/day-seconds"); t = t + getprop("sim/time/local-offset"); var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 9000.0 + rand() * 10000.0; var T = 20.0 + rand() * 15.0; var spread = 8.0 + 2.0 * rand(); var D = T - spread; var p = 970 + rand() * 10.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # first weather info for tile center (lat, lon, visibility, temperature, dew point, pressure) local_weather.set_weather_station(blat, blon, alt_offset, vis, T, D, p * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0; var strength = 0.0; # bias Cumulus clouds towards larger sizes due to lots of water vapour local_weather.convective_size_bias = 0.3 + rand() * 0.3; # tropical weather has a strong daily variation, call thunderstorm only in the correct afternoon time window var t_factor = 0.5 * (1.0-math.cos((t * sec_to_rad)-0.9)); var rn = rand(); if (rn > (t_factor * t_factor * t_factor * t_factor)) # call a normal convective cloud system { strength = 1.0 + rand() * 0.2; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 15000.0, alt+alt_offset, vis + 20000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.7, alt+alt_offset, alt+alt_offset + 2500.0); } else { # a random selection of different possible thunderstorm cloud configuration scenarios rn = rand(); if (rand() < small_scale_persistence) {rn = rnd_store;} else {rnd_store = rn;} if (rn > 0.2) { # cloud scenario 1: 1-2 medium sized storms x = 2.0 * (rand()-0.5) * 12000; y = 2.0 * (rand()-0.5) * 12000; if (rand() > 0.6) {create_medium_thunderstorm(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt+alt_offset, alpha);} else {create_small_thunderstorm(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt+alt_offset, alpha);} if (rand() > 0.5) # we do a second thunderstorm { x = 2.0 * (rand()-0.5) * 12000; y = 2.0 * (rand()-0.5) * 12000; if (rand() > 0.8) {create_medium_thunderstorm(blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset, alpha);} else {create_small_thunderstorm(blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset, alpha);} } # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 12000.0, alt+alt_offset, vis + 20000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.65, alt+alt_offset, alt+alt_offset + 2500.0); } else if (rn > 0.0) { # cloud scenario 2: Single big storm x = 2.0 * (rand()-0.5) * 12000; y = 2.0 * (rand()-0.5) * 12000; create_big_thunderstorm(blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset, alpha); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 12000.0, alt+alt_offset, vis + 20000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.65, alt+alt_offset, alt+alt_offset + 2500.0); } # the convective layer var strength = 0.5 * t_factor; var n = int(4000 * strength) * 0.2; local_weather.cumulus_exclusion_layer(blat, blon, alt+alt_offset, n, 20000.0, 20000.0, alpha, 0.3,1.4 , size(elat), elat, elon, erad); local_weather.cumulus_exclusion_layer(blat, blon, alt+alt_offset, n, 20000.0, 20000.0, alpha, 1.9,2.5 , size(elat), elat, elon, erad); # some turbulence in the convection layer local_weather.create_effect_volume(3, blat, blon, 20000.0, 20000.0, alpha, 0.0, alt+3000.0+alt_offset, -1, -1, -1, 0.4, -1,0 ,-1); } # end thundercloud placement # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # Thunderstorms #################################### var set_thunderstorms_tile = func { setprop(lw~"tiles/code","thunderstorms"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 9000.0 + rand() * 10000.0; var T = 10.0 + rand() * 15.0; var spread = 8.0 + 2.0 * rand(); var D = T - spread; var p = 1000 + rand() * 10.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # first weather info for tile center (lat, lon, visibility, temperature, dew point, pressure) local_weather.set_weather_station(blat, blon, alt_offset, vis, T, D, p * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0; var strength = 0.0; # bias Cumulus clouds towards larger sizes due to lots of water vapour local_weather.convective_size_bias = 0.3 + rand() * 0.3; # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 12000.0, alt+alt_offset, vis + 20000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.65, alt+alt_offset, alt+alt_offset + 2500.0); var rn = rand(); if (rand() < small_scale_persistence) {rn = rnd_store;} else {rnd_store = rn;} create_thunderstorm_scenario (blat, blon, alt + alt_offset, alpha); # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # Coldfront #################################### var set_coldfront_tile = func { setprop(lw~"tiles/code","coldfront"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 20000.0 + rand() * 10000.0; var T = 20.0 + rand() * 8.0; var spread = 8.0 + 2.0 * rand(); var D = T - spread; var p = 1005 + rand() * 10.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # first weather info for tile (lat, lon, visibility, temperature, dew point, pressure) # after the front x = 15000.0; y = 15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T-3.0, D-3.0, p * hp_to_inhg); x = -15000.0; y = 15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T-3.0, D-3.0, p * hp_to_inhg); # before the front x = 15000.0; y = -15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis*0.7, T+3.0, D+3.0, (p-2.0) * hp_to_inhg); x = -15000.0; y = -15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis*0.7, T+3.0, D+3.0, (p-2.0) * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0; var strength = 0.0; # thunderstorms first for (var i =0; i < 3; i=i+1) { x = 2.0 * (rand()-0.5) * 15000; y = 2.0 * (rand()-0.5) * 2000 + 5000.0; if (rand() > 0.7) {create_medium_thunderstorm(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt+alt_offset, alpha);} else {create_small_thunderstorm(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt+alt_offset, alpha);} } # next the dense cloud layer underneath the thunderstorms x = 0.0; y = 5000.0; var strength = 0.3; var n = int(4000 * strength) * 0.2; local_weather.cumulus_exclusion_layer(blat+get_lat(x,y,phi), blon+ get_lon(x,y,phi), alt+alt_offset, n, 20000.0, 10000.0, alpha, 1.5,2.5 , size(elat), elat, elon, erad); # then leading and traling Cumulus x = 0.0; y = 15500.0; strength = 1.0; n = int(4000 * strength) * 0.15; local_weather.cumulus_exclusion_layer(blat+get_lat(x,y,phi), blon+ get_lon(x,y,phi), alt+alt_offset, n, 20000.0, 2000.0, alpha, 0.5,1.8 , size(elat), elat, elon, erad); x = 0.0; y = -5500.0; strength = 1.0; n = int(4000 * strength) * 0.15; local_weather.cumulus_exclusion_layer(blat+get_lat(x,y,phi), blon+ get_lon(x,y,phi), alt+alt_offset, n, 20000.0, 2000.0, alpha, 0.5,1.8 , size(elat), elat, elon, erad); # finally some thin stratus underneath the Cumulus x = 0.0; y = 13000.0; local_weather.create_streak("Stratus (thin)",blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset,0.0,20,2000.0,0.2,1200.0,3,1500.0,0.2,1200.0,alpha,1.0); x = 0.0; y = -3000.0; local_weather.create_streak("Stratus (thin)",blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset,0.0,20,2000.0,0.2,1200.0,3,1500.0,0.2,1200.0,alpha,1.0); # some turbulence in the convection layer x=0.0; y = 5000.0; local_weather.create_effect_volume(3, blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 20000.0, 11000.0, alpha, 0.0, alt+3000.0+alt_offset, -1, -1, -1, 0.4, -1,0 ,-1); # some rain and reduced visibility in its core x=0.0; y = 5000.0; local_weather.create_effect_volume(3, blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 20000.0, 8000.0, alpha, 0.0, alt+alt_offset, 10000.0, 0.1, -1, -1, -1,0,-1 ); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 20000.0, 0.0, alt+alt_offset +20000.0, alt+alt_offset + 25000.0, 0.6, alt+alt_offset, alt+alt_offset + 2500.0); # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # Warmfront 1 #################################### var set_warmfront1_tile = func { setprop(lw~"tiles/code","warmfront1"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; if (local_weather.presampling_flag == 0) {var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft");} else {var alt_offset = getprop(lw~"tmp/tile-alt-layered-ft");} # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 20000.0 + rand() * 5000.0; var T = 10.0 + rand() * 8.0; var spread = 9.0 + 4.0 * rand(); var D = T - spread; var p = 1005 + rand() * 10.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # first weather info for tile (lat, lon, visibility, temperature, dew point, pressure) # after the front x = 15000.0; y = 15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T+2.0, D+1.0, p * hp_to_inhg); x = -15000.0; y = 15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T+2.0, D+1.0, p * hp_to_inhg); # before the front x = 15000.0; y = -15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T, D, p * hp_to_inhg); x = -15000.0; y = -15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T, D, p * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0; # some weak Cumulus development var strength = 0.1 + rand() * 0.1; local_weather.create_cumosys(blat,blon, alt + alt_offset, get_n(strength), 20000.0); # high Cirrus leading x = 2.0 * (rand()-0.5) * 1000; y = 2.0 * (rand()-0.5) * 1000 - 9000.0; local_weather.create_streak("Cirrus",blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 25000.0+alt+alt_offset,1500.0,3,11000.0,0.0, 3000.0, 2,11000.0,0.0,3000.0,alpha ,1.0); # followed by random patches of Cirrostratus for (var i=0; i<6; i=i+1) { var x = 2.0 * (rand()-0.5) * 15000; var y = 2.0 * (rand()-0.5) * 10000 + 10000; var beta = (rand() -0.5) * 180.0; var alt_shift = 0.0; if (local_weather.hardcoded_clouds_flag == 1) {alt_shift = local_weather.offset_map["Cirrostratus"];} local_weather.create_streak("Cirrostratus",blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 18000 + alt + alt_offset - alt_shift,300.0,4,2300.0,0.2,600.0,4,2300.0,0.2,600.0,alpha+beta,1.0); } # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 8000.0, alt+alt_offset, vis + 10000.0, rand() * 0.1, alt+alt_offset +18000.0, alt+alt_offset + 22000.0, 0.8, alt+alt_offset, alt+alt_offset + 2500.0); # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # Warmfront 2 #################################### var set_warmfront2_tile = func { setprop(lw~"tiles/code","warmfront2"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; if (local_weather.presampling_flag == 0) {var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft");} else {var alt_offset = getprop(lw~"tmp/tile-alt-layered-ft");} # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 15000.0 + rand() * 5000.0; var T = 13.0 + rand() * 8.0; var spread = 8.0 + 2.0 * rand(); var D = T - spread; var p = 1005 + rand() * 10.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # first weather info for tile (lat, lon, visibility, temperature, dew point, pressure) # after the front x = 15000.0; y = 15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T+2.0, D+1.0, p * hp_to_inhg); x = -15000.0; y = 15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T+2.0, D+1.0, p * hp_to_inhg); # before the front x = 15000.0; y = -15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T, D, p * hp_to_inhg); x = -15000.0; y = -15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T, D, p * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0; var strength = 0.0; # followed by random patches of Cirrostratus var alt_shift = 0.0; if (local_weather.hardcoded_clouds_flag == 1) {alt_shift = local_weather.offset_map["Cirrostratus"];} for (var i=0; i<3; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 5000 - 15000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Cirrostratus",blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 15000 + alt + alt_offset - alt_shift,300.0,4,2300.0,0.2,600.0,4,2300.0,0.2,600.0,alpha+beta,1.0); } # patches of thin Altostratus for (var i=0; i<14; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 9000 - 10000.0; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Stratus (thin)",blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset +12000.0,300.0,4,950.0,0.2,500.0,6,950.0,0.2,500.0,alpha+beta,1.0); } # patches of structured Stratus for (var i=0; i<10; i=i+1) { var x = 2.0 * (rand()-0.5) * 9000; var y = 2.0 * (rand()-0.5) * 9000 + 2000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Stratus (structured)",blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset+9000.0,300.0,5,900.0,0.2,500.0,7,900.0,0.2,500.0,alpha+beta,1.0); } # merging with a broken Stratus layer var x = 0.0; var y = 8000.0; local_weather.create_streak("Stratus",blat +get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset +5000.0,1000.0,30,0.0,0.2,20000.0,10,0.0,0.2,12000.0,alpha,1.0); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 6000.0, alt+alt_offset, vis + 8000.0, 0.15 + rand() * 0.15, alt+alt_offset +17000.0, alt+alt_offset + 21000.0, 0.7, alt+alt_offset, alt+alt_offset + 2500.0); # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # Warmfront 3 #################################### var set_warmfront3_tile = func { setprop(lw~"tiles/code","warmfront3"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; if (local_weather.presampling_flag == 0) {var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft");} else {var alt_offset = getprop(lw~"tmp/tile-alt-layered-ft");} # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 12000.0 + rand() * 3000.0; var T = 15.0 + rand() * 7.0; var spread = 7.0 + 2.0 * rand(); var D = T - spread; var p = 1005 + rand() * 10.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # first weather info for tile (lat, lon, visibility, temperature, dew point, pressure) # after the front x = 15000.0; y = 15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T+2.0, D+1.0, p * hp_to_inhg); x = -15000.0; y = 15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T+2.0, D+1.0, p * hp_to_inhg); # before the front x = 15000.0; y = -15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T, D, p * hp_to_inhg); x = -15000.0; y = -15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T, D, p * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0 + local_weather.cloud_vertical_size_map["Nimbus"] * 0.5 * m_to_ft; var strength = 0.0; # closed Stratus layer var x = 0.0; var y = -8000.0; local_weather.create_streak("Stratus",blat +get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset +1000.0,500.0,32,1250.0,0.2,400.0,20,1250.0,0.2,400.0,alpha,1.0); # merging with a Nimbostratus layer var x = 0.0; var y = 8000.0; local_weather.create_streak("Nimbus",blat +get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset,500.0,32,1250.0,0.0,200.0,20,1250.0,0.0,200.0,alpha,1.0); # some rain beneath the stratus x=0.0; y = -10000.0; local_weather.create_effect_volume(3, blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 20000.0, 10000.0, alpha, 0.0, alt+alt_offset+1000, vis * 0.7, 0.1, -1, -1, -1,0 ,-1); # heavier rain beneath the Nimbostratus x=0.0; y = 10000.0; local_weather.create_effect_volume(3, blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 20000.0, 10000.0, alpha, 0.0, alt+alt_offset, vis * 0.5, 0.3, -1, -1, -1,0,-1 ); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 6000.0, alt+alt_offset, vis + 8000.0, 0.05 + rand() * 0.05, alt+alt_offset +16000.0, alt+alt_offset + 20000.0, 0.6, alt+alt_offset, alt+alt_offset + 2500.0); # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # Warmfront 4 #################################### var set_warmfront4_tile = func { setprop(lw~"tiles/code","warmfront4"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; if (local_weather.presampling_flag == 0) {var alt_offset = getprop(lw~"tmp/tile-alt-offset-ft");} else {var alt_offset = getprop(lw~"tmp/tile-alt-layered-ft");} # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); # get probabilistic values for the weather parameters var vis = 12000.0 + rand() * 3000.0; var T = 17.0 + rand() * 6.0; var spread = 5.0 + 2.0 * rand(); var D = T - spread; var p = 1005 + rand() * 10.0; p = adjust_p(p); if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} # first weather info for tile (lat, lon, visibility, temperature, dew point, pressure) # after the front x = 15000.0; y = 15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T+2.0, D+1.0, p * hp_to_inhg); x = -15000.0; y = 15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T+2.0, D+1.0, p * hp_to_inhg); # before the front x = 15000.0; y = -15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T, D, p * hp_to_inhg); x = -15000.0; y = -15000.0; local_weather.set_weather_station(blat +get_lat(x,y,phi), blon + get_lon(x,y,phi), alt_offset, vis, T, D, p * hp_to_inhg); # altitude for the lowest layer var alt = spread * 400.0 + local_weather.cloud_vertical_size_map["Nimbus"] * 0.5 * m_to_ft; var strength = 0.0; # low Nimbostratus layer var x = 0.0; var y = -5000.0; local_weather.create_streak("Nimbus",blat +get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset,500.0,32,1250.0,0.0,200.0,24,1250.0,0.0,200.0,alpha,1.0); # a little patchy structured Stratus above for effect create_2_8_sstratus(blat, blon, alt+alt_offset+3000.0, alpha); # eventually breaking up var x = 0.0; var y = 14000.0; local_weather.create_streak("Nimbus",blat +get_lat(x,y,phi), blon+get_lon(x,y,phi), alt+alt_offset,500.0,25,1600.0,0.2,200.0,9,1400.0,0.3,200.0,alpha,1.0); # rain beneath the Nimbostratus x=0.0; y = -5000.0; local_weather.create_effect_volume(3, blat+get_lat(x,y,phi), blon+get_lon(x,y,phi), 20000.0, 15000.0, alpha, 0.0, alt+alt_offset, vis * 0.5, 0.3, -1, -1, -1,0 ,-1); # and specify the atmosphere local_weather.set_atmosphere_ipoint(blat, blon, vis + 10000.0, alt+alt_offset, vis + 12000.0, 0.1, alt+alt_offset +16000.0, alt+alt_offset + 20000.0, 0.5, alt+alt_offset, alt+alt_offset + 2500.0); # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # METAR #################################### var set_METAR_tile = func { setprop(lw~"tiles/code","METAR"); tile_start(); var x = 0.0; var y = 0.0; var lat = 0.0; var lon = 0.0; var alpha = getprop("/environment/metar/base-wind-dir-deg"); var phi = alpha * math.pi/180.0; # it seems more recent Flightgear versions have absolute altitude # var metar_alt_offset = 700.0 + getprop("/environment/metar/station-elevation-ft"); var metar_alt_offset = 700.0; # print("metar_alt_offset", metar_alt_offset); # get the local time of the day in seconds var t = getprop("sim/time/utc/day-seconds"); t = t + getprop("sim/time/local-offset"); # get tile center coordinates var blat = getprop(lw~"tiles/tmp/latitude-deg"); var blon = getprop(lw~"tiles/tmp/longitude-deg"); calc_geo(blat); var rain_norm = getprop("/environment/metar/rain-norm"); var snow_norm = getprop("/environment/metar/snow-norm"); var p = inhg_to_hp * getprop("/environment/metar/pressure-sea-level-inhg"); # now get the cloud layer info var layers = props.globals.getNode("/environment/metar/clouds", 1).getChildren("layer"); var n_layers = size(layers); # the system initializes with 4 layers, but who knows... var n = 0; # start with lowest layer # now determine the nature of the lowest layer var cumulus_flag = 1; # default assumption - the lowest layer is cumulus var thunderstorm_flag = 0; var cover_low = 8 - 2 * layers[0].getNode("coverage-type").getValue(); # conversion to oktas var alt_low = layers[0].getNode("elevation-ft").getValue(); # print("alt_low: ", alt_low); if ((alt_low < 0.0) or (cover_low ==0)) # we have to guess a value for the convective altitude for the visibility model {alt_low = 8000.0;} # first check a few obvious criteria if (cover_low == 8) {cumulus_flag = 0;} # overcast sky is unlikely to be Cumulus, and we can't render it anyway if ((rain_norm > 0.0) or (snow_norm > 0.0)) {cumulus_flag = 0;} # Cumulus usually doesn't rain if (alt_low > 7000.0) {cumulus_flag = 0;} # Cumulus are low altitude clouds # now try matching time evolution of cumuli if ((cover_low == 5) or (cover_low == 6) or (cover_low == 7)) # broken { if ((t < 39600) or (t > 68400)) {cumulus_flag = 0;} # not before 11:00 and not after 19:00 } if ((cover_low == 3) or (cover_low == 4)) # scattered { if ((t < 32400) or (t > 75600)) {cumulus_flag = 0;} # not before 9:00 and not after 21:00 } # now see if there is a layer shading convective development var coverage_above = 8 - 2 * layers[1].getNode("coverage-type").getValue(); var coverage_above2 = 8 - 2 * layers[2].getNode("coverage-type").getValue(); if (coverage_above2 > coverage_above) {coverage_above = coverage_above2;} if (coverage_above > 6) {cumulus_flag = 0;} # no Cumulus with strong layer above # never do Cumulus when there's a thunderstorm if (getprop(lw~"METAR/thunderstorm-flag") ==1) {cumulus_flag = 0; thunderstorm_flag = 1;} # if cumulus_flag is still 1 at this point, the lowest layer is Cumulus # see if we need to adjust its strength if ((cumulus_flag == 1) and (cover_low > 0)) { if ((cover_low < 4) and (t > 39600) and (t < 68400)) {var strength = 0.4;} if ((cover_low < 2) and (t > 39600) and (t < 68400)) {var strength = 0.2;} else {var strength = 1.0;} local_weather.create_cumosys(blat,blon, alt_low+metar_alt_offset,get_n(strength), 20000.0); n = n + 1; # do not start parsing with lowest layer } else {var strength = 0.0;} # if thunderstorm_flag is 1, we do the lowest layer as thunderstorm scenario, somewhat ignoring the coverage info if (thunderstorm_flag == 1) { create_thunderstorm_scenario(blat, blon, alt_low+metar_alt_offset, alpha); n = n + 1; # do not start parsing with lowest layer } for (var i = n; i 0) { rain_norm = 0.0; snow_norm = 0.0;} # rain and snow fall only from the lowest layer if (altitude < 9000.0) # draw Nimbostratus or Stratus models { if (cover == 8) { if ((altitude < 2000) or (rain_norm > 0.3)) {create_8_8_nimbus_rain(blat, blon, altitude+metar_alt_offset, alpha, rain_norm);} else {create_8_8_stratus_rain(blat, blon, altitude+metar_alt_offset, alpha, rain_norm);} } else if ((cover < 8) and (cover > 4)) { if (cumulus_flag == 1) { create_4_8_sstratus_patches(blat, blon, altitude+metar_alt_offset, alpha); } else { if ((rain_norm > 0.1) and (altitude < 5000.0)) { create_6_8_nimbus_rain(blat, blon, altitude+metar_alt_offset, alpha, rain_norm); } else if (rain_norm > 0.0) { create_6_8_stratus_rain(blat, blon, altitude+metar_alt_offset, alpha, rain_norm); } else { if ((p > 1010.0) and (i == 0)) # the lowest layer may be Stratocumulus { create_6_8_stratocumulus(blat, blon, altitude+metar_alt_offset, alpha); } else { if (rand() > 0.5) {create_6_8_stratus(blat, blon, altitude+metar_alt_offset, alpha);} else {create_6_8_stratus_undulatus(blat, blon, altitude+metar_alt_offset, alpha);} } } } } else if ((cover == 3) or (cover == 4)) { if ((p > 1010.0) and (i == 0)) # the lowest layer may be Stratocumulus { create_4_8_stratocumulus(blat, blon, altitude+metar_alt_offset, alpha); } else { var rn = rand(); if (rn > 0.75) {create_4_8_stratus(blat, blon, altitude+metar_alt_offset, alpha);} else if (rn > 0.5) {create_4_8_stratus_patches(blat, blon, altitude+metar_alt_offset, alpha);} else if (rn > 0.25) {create_4_8_sstratus_patches(blat, blon, altitude+metar_alt_offset, alpha);} else if (rn > 0.0) {create_4_8_sstratus_undulatus(blat, blon, altitude+metar_alt_offset, alpha);} } } else { if (cumulus_flag == 0) { var rn = rand(); if (rn > 0.5) {create_2_8_stratus(blat, blon, altitude+metar_alt_offset, alpha);} else if (rn > 0.0) {create_2_8_sstratus(blat, blon, altitude+metar_alt_offset, alpha);} } else { create_2_8_altocumulus_streaks(blat, blon, altitude+metar_alt_offset, alpha); } } } # end if altitude else if ((altitude > 9000.0) and (altitude < 20000.0)) # select thin cloud layers { if (cover == 8) { if (altitude < 14000.0) {create_8_8_tstratus(blat, blon, altitude+metar_alt_offset, alpha);} else {create_8_8_cirrostratus(blat, blon, altitude+metar_alt_offset, alpha);} } else if (cover > 4) { if (altitude < 14000.0) {create_6_8_tstratus_undulatus(blat, blon, altitude+metar_alt_offset, alpha);} else {create_6_8_cirrostratus(blat, blon, altitude+metar_alt_offset, alpha);} } else if (cover > 2) { var rn = rand(); if (rn > 0.75) {create_4_8_tstratus_patches(blat, blon, altitude+metar_alt_offset, alpha);} else if (rn > 0.5) {create_4_8_alttstratus_streaks(blat, blon, altitude+metar_alt_offset, alpha);} else if (rn > 0.25) {create_4_8_alttstratus_patches(blat, blon, altitude+metar_alt_offset, alpha);} else if (rn > 0.0) {create_4_8_tstratus_undulatus(blat, blon, altitude+metar_alt_offset, alpha);} } else { if (altitude < 14000.0) { var rn = rand(); if (rn > 0.66) {create_2_8_tstratus(blat, blon, altitude+metar_alt_offset, alpha);} else if (rn > 0.33) {create_2_8_sstratus(blat, blon, altitude+metar_alt_offset, alpha);} else {create_2_8_alttstratus(blat, blon, altitude+metar_alt_offset, alpha);} } else { var rn = rand(); if (rn > 0.5) {create_2_8_cirrocumulus(blat, blon, altitude+metar_alt_offset, alpha);} else {create_2_8_alttstratus(blat, blon, altitude+metar_alt_offset, alpha);} } } } # end if altitude else { if (cover == 8) {create_8_8_cirrostratus(blat, blon, altitude+metar_alt_offset, alpha);} else if (cover > 4) {create_6_8_cirrostratus(blat, blon, altitude+metar_alt_offset, alpha);} else if (cover > 2) { var rn = rand(); if (rn > 0.5) {create_4_8_cirrostratus_patches(blat, blon, altitude+metar_alt_offset, alpha);} else {create_4_8_cirrostratus_undulatus(blat, blon, altitude+metar_alt_offset, alpha);} } else { var rn = rand(); if (rn > 0.5) {create_2_8_cirrostratus(blat, blon, altitude+metar_alt_offset, alpha);} else {create_1_8_cirrocumulus(blat, blon, altitude+metar_alt_offset, alpha);} } } } # end for # store convective altitude and strength append(weather_dynamics.tile_convective_altitude,alt_low); append(weather_dynamics.tile_convective_strength,strength); tile_finished(); } #################################### # METAR station setup #################################### var set_METAR_weather_station = func { # get the METAR position info var station_lat = getprop("/environment/metar/station-latitude-deg"); var station_lon = getprop("/environment/metar/station-longitude-deg"); var metar_alt_offset = 700.0 + getprop("/environment/metar/station-elevation-ft"); # get the weather parameters var vis = getprop("/environment/metar/max-visibility-m"); var T = getprop("/environment/metar/temperature-sea-level-degc"); var D = getprop("/environment/metar/dewpoint-sea-level-degc"); var p = getprop("/environment/metar/pressure-sea-level-inhg"); var rain_norm = getprop("/environment/metar/rain-norm"); var snow_norm = getprop("/environment/metar/snow-norm"); var windspeed = getprop("/environment/metar/base-wind-speed-kt"); var wind_range_from = getprop("/environment/metar/base-wind-range-from"); var wind_range_to = getprop("/environment/metar/base-wind-range-to"); var gust_strength = getprop("/environment/metar/gust-wind-speed-kt"); var alpha = getprop("/environment/metar/base-wind-dir-deg"); # some METAR report just above max. visibility, if so we guess visibility based on pressure var is_visibility_max = 0; if (vis == 9999) {is_visibility_max = 1;} if ((vis > 16093) and (vis < 16094)) # that's 10 nm {is_visibility_max = 1;} if (is_visibility_max == 1) { if (p * inhg_to_hp < 1000.0) {vis = 10000.0 + 5000 * rand();} else if (p * inhg_to_hp < 1010.0) {vis = 15000.0 + 7000 * rand();} else if (p * inhg_to_hp < 1020.0) {vis = 22000.0 + 14000.0 * rand();} else {vis = 30000.0 + 15000.0 * rand();} if (realistic_visibility_flag == 1) {vis = vis * realistic_visibility_multiplyer;} } # set the station local_weather.set_weather_station(station_lat, station_lon, metar_alt_offset, vis, T, D, p); # get cloud layer info for lighting var coverage1 = 8 - 2 * getprop("/environment/metar/clouds/layer[0]/coverage-type"); var layer_alt1 = getprop("/environment/metar/clouds/layer[0]/elevation-ft"); var coverage2 = 8 - 2 * getprop("/environment/metar/clouds/layer[1]/coverage-type"); var layer_alt2 = getprop("/environment/metar/clouds/layer[1]/elevation-ft"); var coverage3 = 8 - 2 * getprop("/environment/metar/clouds/layer[2]/coverage-type"); var layer_alt3 = getprop("/environment/metar/clouds/layer[2]/elevation-ft"); var coverage4 = 8 - 2 * getprop("/environment/metar/clouds/layer[3]/coverage-type"); var layer_alt4 = getprop("/environment/metar/clouds/layer[3]/elevation-ft"); # determine the altitude of the main shading layer # default assumption - the lowest layer shades var alt_shade = layer_alt1; var coverage_shade = coverage1; var coverage_mult = 1.0; # if a higher layer is more opaque, it determines the shading unless it is a thin layer if ((coverage2 >= coverage1) and (layer_alt2 < 14000.0)) {alt_shade = layer_alt2; coverage_shade = coverage2; coverage_mult = 0.9;} if ((coverage3 >= coverage1) and (coverage3 >= coverage2) and (layer_alt3 < 14000.0)) {alt_shade = layer_alt3; coverage_shade = coverage3; coverage_mult = 0.8;} # determine the amount of shading # default assumption: no clouds var shade = 1.0; if (coverage_shade < 1) # clear sky, we need to specify an altitude for the model {shade = 0.9; alt_shade = 9000.0;} else if (coverage_shade < 3) {shade = 0.8;} else if (coverage_shade < 5) {shade = 0.7;} else if (coverage_shade < 8) {shade = 0.6;} else if (coverage_shade == 8) {shade = 0.55;} shade = shade * coverage_mult; # see if we have any high-altitude clouds var ovcst = 0.0; var ovcst_alt = 20000.0; if (layer_alt1 > 20000.0) {ovcst_alt = layer_alt1; ovcst = ovcst + rand() * 0.1;} if (layer_alt2 > 20000.0) {ovcst_alt = layer_alt2; ovcst = ovcst + rand() * 0.1;} if (layer_alt3 > 20000.0) {ovcst_alt = layer_alt3; ovcst = ovcst + rand() * 0.1;} if (layer_alt4 > 20000.0) {ovcst_alt = layer_alt4; ovcst = ovcst + rand() * 0.1;} # and specify the atmosphere - currently default only local_weather.set_atmosphere_ipoint(station_lat, station_lon, vis + 10000.0, metar_alt_offset + alt_shade, vis + 20000.0, ovcst, ovcst_alt+metar_alt_offset - 5000.0, ovcst_alt+metar_alt_offset, shade, layer_alt1+metar_alt_offset, alt_shade+metar_alt_offset + 2500.0); # if we use aloft interpolated winds with METAR, also set a new wind interpolation point if ((local_weather.wind_model_flag == 5) and (getprop(lw~"tiles/tile-counter") !=1)) { # if zero winds are reported, we do not rotate the tile to face north but use the last value if ((alpha == 0.0) and (windspeed == 0.0)) { alpha = getprop(lw~"tmp/tile-orientation-deg"); var phi = alpha * math.pi/180.0; } var boundary_correction = 1.0/local_weather.get_slowdown_fraction(); local_weather.set_wind_ipoint_metar(station_lat, station_lon, alpha, boundary_correction * windspeed); } # also compute and set gust wind info var gust_angvar = 0.5 * weather_tile_management.relangle(wind_range_from, wind_range_to); if ((gust_strength > 0.0) or (gust_angvar > 0.0)) { var gust_relative_strength = (gust_strength - windspeed)/windspeed; setprop(lw~"tmp/gust-frequency-hz", 0.2 + rand()*0.8); } else { var gust_relative_strength = 0.0; setprop(lw~"tmp/gust-frequency-hz", 0.0); } setprop(lw~"tmp/gust-relative-strength", gust_relative_strength); setprop(lw~"tmp/gust-angular-variation-deg", gust_angvar); # and mark that we have used this station setprop(lw~"METAR/station-id",getprop("/environment/metar/station-id")); } #################################### # mid-level cloud setup calls #################################### var create_8_8_tstratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) { alt = alt - local_weather.offset_map["Stratus_thin"]; local_weather.create_streak("Stratus (thin)",lat, lon, alt,500.0,40,1000.0,0.0,400.0,40,1000.0,0.0,400.0,alpha,1.0); } else { local_weather.create_streak("Stratus (thin)",lat, lon, alt,500.0,32,1250.0,0.0,400.0,32,1250.0,0.0,400.0,alpha,1.0); } } var create_8_8_cirrostratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Cirrostratus"];} local_weather.create_streak("Cirrostratus",lat,lon,alt,500.0,30,1250.0,0.0,400.0,30,1250.0,0.0,400.0,alpha,1.0); } var create_8_8_nimbus = func (lat, lon, alt, alpha) { local_weather.create_streak("Nimbus",lat, lon, alt,500.0,32,1250.0,0.0,200.0,32,1250.0,0.0,200.0,alpha,1.0); } var create_8_8_nimbus_var1 = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {var alt_eff = alt - local_weather.offset_map["Nimbus"]; } var phi = alpha * math.pi/180.0; local_weather.create_streak("Nimbus",lat, lon, alt_eff,500.0,35,1150.0,0.0,200.0,35,1150.0,0.0,200.0,alpha,1.0); for (var i = 0; i < 3; i=i+1) { var x = -15000.0 + 30000.0 * rand(); var y = -15000.0 + 30000.0 * rand(); local_weather.create_streak("Stratocumulus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt+600.0,200.0,11,1100.0,0.1,800.0,8,1100.0,0.1,800.0,alpha,1.4); } } var create_8_8_nimbus_var2 = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {var alt_eff = alt - local_weather.offset_map["Nimbus"]; } var phi = alpha * math.pi/180.0; local_weather.create_streak("Nimbus",lat, lon, alt_eff,500.0,35,1150.0,0.0,200.0,35,1150.0,0.0,200.0,alpha,1.0); for (var i=0; i<8; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Stratus (structured)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt+1200.0,300.0,5,900.0,0.2,500.0,7,900.0,0.2,500.0,alpha+beta,1.0); } } var create_8_8_nimbus_var3 = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {var alt_eff = alt - local_weather.offset_map["Nimbus"]; } var phi = alpha * math.pi/180.0; local_weather.create_streak("Nimbus",lat, lon, alt_eff,500.0,35,1150.0,0.0,200.0,35,1150.0,0.0,200.0,alpha,1.0); for (var i=0; i<6; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Stratus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt+1600.0,300.0,6,1200.0,0.2,700.0,6,1200.0,0.2,700.0,alpha+beta,1.0); } } var create_8_8_nimbus_rain = func (lat, lon, alt, alpha, rain) { if (local_weather.detailed_clouds_flag == 0) {local_weather.create_streak("Nimbus",lat, lon, alt,500.0,32,1250.0,0.0,200.0,32,1250.0,0.0,200.0,alpha,1.0);} else { #print(local_weather.offset_map["Nimbus"]); var rn = rand(); if (rn > 0.66) {create_8_8_nimbus_var1(lat, lon, alt, alpha);} else if (rn > 0.33) {create_8_8_nimbus_var2(lat, lon, alt, alpha);} else {create_8_8_nimbus_var3(lat, lon, alt, alpha);} } if (rain > 0.1) { local_weather.create_effect_volume(3, lat, lon, 20000.0, 20000.0, alpha, 0.0, alt+900.0, 500.0 + (1.0 - 0.5 * rain) * 5500.0, 0.5 * rain , -1, -1, -1,0 ,0.95); local_weather.create_effect_volume(3, lat , lon, 16000.0, 16000.0, alpha, 0.0, alt - 300.0, 500.0 + (1.0-rain) * 5500.0, rain, -1, -1, -1,0 ,0.9); } else { local_weather.create_effect_volume(3, lat, lon, 20000.0, 20000.0, alpha, alt-1500.0, alt+900.0, 2000.0, -1 , -1, -1, -1,0 ,-1); local_weather.create_effect_volume(3, lat, lon, 20000.0, 20000.0, alpha, 0.0, alt, -1, rain , -1, -1, -1,0 ,0.9); } } var create_8_8_stratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus"];} local_weather.create_streak("Stratus",lat, lon, alt,500.0,32,1250.0,0.0,400.0,32,1250.0,0.0,400.0,alpha,1.0); } var create_8_8_stratus_rain = func (lat, lon, alt, alpha, rain) { create_8_8_stratus(lat, lon, alt, alpha); if (rain > 0.1) { local_weather.create_effect_volume(3, lat, lon, 20000.0, 20000.0, alpha, 0.0, alt, 500.0 + (1.0 - 0.5 * rain) * 5500.0, 0.5 * rain , -1, -1, -1,0 ,-1); local_weather.create_effect_volume(3, lat , lon, 16000.0, 16000.0, alpha, 0.0, alt - 300.0, 500.0 + (1.0-rain) * 5500.0, rain, -1, -1, -1,0 ,0.9); } else { local_weather.create_effect_volume(3, lat, lon, 20000.0, 20000.0, alpha, 0.0, alt, -1, rain , -1, -1, -1,0 ,0.9); } } var create_6_8_stratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) { alt = alt - local_weather.offset_map["Stratus"]; for (var i = 0; i < 20; i = i + 1) { var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; local_weather.create_streak("Stratus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,500.0,5,2300.0,0.2,500.0,5,2300.0,0.2,500.0,alpha,1.0); } } else {local_weather.create_streak("Stratus",lat, lon, alt,500.0,20,0.0,0.2,20000.0,20,0.0,0.2,20000.0,alpha,1.0);} } var create_6_8_nimbus_rain = func (lat, lon, alt, alpha, rain) { var phi = alpha * math.pi/180.0; var alt_cloud = alt; if (local_weather.hardcoded_clouds_flag == 1) {alt_cloud = alt_cloud - 3000.0;} for (var i = 0; i < 3; i = i + 1) { var x = 2.0 * (rand()-0.5) * 2000.0 + i * 12000.0 - 12000.0; var y = 2.0 * (rand()-0.5) * 12000.0; var beta = rand() * 360.0; local_weather.create_layer("Nimbus", lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt_cloud, 500.0, 12000.0, 7000.0, beta, 1.0, 0.2, 1, 1.0); if (rain > 0.1) { local_weather.create_effect_volume(2, lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), 10000.0, 6000.0, beta, 0.0, alt+900, 500.0 + (1.0-0.5*rain) * 5500.0, 0.5 * rain, -1, -1, -1,0,0.95 ); local_weather.create_effect_volume(2, lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), 9000.0, 5000.0, beta, 0.0, alt-300.0, 500.0 + (1.0-rain) * 5500.0, rain, -1, -1, -1,0,0.8); } else { local_weather.create_effect_volume(2, lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), 10000.0, 6000.0, beta, 0.0, alt, -1, rain, -1, -1, -1,0, 0.8 ); local_weather.create_effect_volume(2, lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), 10000.0, 6000.0, beta, alt-1500.0, alt+900.0, 2000.0, -1, -1, -1, -1,0, 0.8 ); } } } var create_6_8_stratus_rain = func (lat, lon, alt, alpha, rain) { var phi = alpha * math.pi/180.0; var alt_cloud = alt; if (local_weather.hardcoded_clouds_flag == 1) {alt_cloud = alt_cloud - local_weather.offset_map["Stratus"];} for (var i = 0; i < 3; i = i + 1) { var x = 2.0 * (rand()-0.5) * 2000.0 + i * 12000.0 - 12000.0; var y = 2.0 * (rand()-0.5) * 12000.0; var beta = rand() * 360.0; local_weather.create_layer("Stratus", lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt_cloud, 500.0, 12000.0, 7000.0, beta, 1.0, 0.2, 0, 0.0); if (rain > 0.1) { local_weather.create_effect_volume(2, lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), 10000.0, 6000.0, beta, 0.0, alt, 500.0 + (1.0-0.5*rain) * 5500.0, 0.5 * rain, -1, -1, -1,0,0.95 ); local_weather.create_effect_volume(2, lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), 9000.0, 5000.0, beta, 0.0, alt-300.0, 500.0 + (1.0-rain) * 5500.0, rain, -1, -1, -1,0,0.8); } else { local_weather.create_effect_volume(2, lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), 10000.0, 6000.0, beta, 0.0, alt, -1, rain, -1, -1, -1,0, 0.8 ); } } } var create_6_8_stratus_undulatus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus"];} local_weather.create_undulatus("Stratus",lat, lon, alt,300.0,10,4000.0,0.1,400.0,50,800.0,0.1,100.0, 1000.0, alpha,1.0); } var create_6_8_tstratus_undulatus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_thin"];} local_weather.create_undulatus("Stratus (thin)",lat, lon, alt,300.0,10,4000.0,0.1,400.0,50,800.0,0.1,100.0, 1000.0, alpha,1.0); } var create_6_8_cirrostratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Cirrostratus"];} local_weather.create_streak("Cirrostratus",lat,lon,alt,500.0,24,1500.0,0.0,900.0,24,1500.0,0.0,900.0,alpha,1.0); } var create_6_8_stratocumulus = func (lat, lon, alt, alpha) { if (local_weather.detailed_clouds_flag == 1) { for (i=0; i< 2; i=i+1) { var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 4000; var y = 2.0 * (rand()-0.5) * 4000; var beta = rand() * 360.0; create_detailed_stratocumulus_bank(lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt, alpha+beta); } } else { create_stratocumulus_bank(lat, lon, alt, alpha); create_stratocumulus_bank(lat, lon, alt, alpha); } } var create_4_8_stratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus"];} var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 15000; var y = 2.0 * (rand()-0.5) * 15000; var beta = rand() * 360.0; local_weather.create_streak("Stratus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,500.0,20,1200.0,0.3,400.0,12,1200.0,0.3,400.0,beta,1.2); var x = 2.0 * (rand()-0.5) * 15000; var y = 2.0 * (rand()-0.5) * 15000; var beta = rand() * 360.0; local_weather.create_streak("Stratus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,500.0,18,1000.0,0.3,400.0,10,1000.0,0.3,400.0,beta,1.5); var x = 2.0 * (rand()-0.5) * 15000; var y = 2.0 * (rand()-0.5) * 15000; var beta = rand() * 360.0; local_weather.create_streak("Stratus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,500.0,15,1000.0,0.3,400.0,18,1000.0,0.3,400.0,beta,2.0); } var create_4_8_stratus_patches = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus"];} for (var i=0; i<16; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Stratus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,4,950.0,0.2,500.0,6,950.0,0.2,500.0,alpha+beta,1.0); } } var create_4_8_tstratus_patches = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_thin"];} for (var i=0; i<22; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; var m = int(3 + rand() * 3); var n = int(3 + rand() * 5); local_weather.create_streak("Stratus (thin)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,m,1000.0,0.2,500.0,n,1000.0,0.2,500.0,alpha+beta,1.0); } } var create_4_8_sstratus_patches = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_structured"];} for (var i=0; i<22; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; var m = int(3 + rand() * 5); var n = int(3 + rand() * 5); local_weather.create_streak("Stratus (structured)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,m,1000.0,0.2,500.0,n,1000.0,0.2,500.0,alpha+beta,1.0); } } var create_4_8_cirrostratus_patches = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Cirrostratus"];} var phi = alpha * math.pi/180.0; for (var i=0; i<6; i=i+1) { var x = 2.0 * (rand()-0.5) * 12000; var y = 2.0 * (rand()-0.5) * 12000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Cirrostratus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,4,2500.0,0.2,600.0,4,2500.0,0.2,600.0,alpha+beta,1.0); } } var create_4_8_cirrostratus_undulatus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Cirrostratus"];} local_weather.create_undulatus("Cirrostratus",lat, lon, alt,300.0,5,8000.0,0.1,400.0,40,1000.0,0.1,100.0, 1500.0, alpha,1.0); } var create_4_8_stratus_undulatus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus"];} var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 5000; var y = 2.0 * (rand()-0.5) * 5000; var tri = 1.5 + 1.5*rand(); var beta = (rand() -0.5) * 60.0; local_weather.create_streak("Stratus",lat+get_lat(x,y+4000,phi), lon+get_lon(x,y+4000,phi), alt,500.0,10,800.0,0.25,400.0,12,2800.0,0.15,600.0,alpha+90.0+beta,tri); local_weather.create_streak("Stratus",lat+get_lat(x,y-4000,phi), lon+get_lon(x,y-4000,phi), alt,500.0,10,800.0,0.25,400.0,12,2800.0,0.15,600.0,alpha+270.0+beta,tri); } var create_4_8_tstratus_undulatus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_thin"];} var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 5000; var y = 2.0 * (rand()-0.5) * 5000; var tri = 1.5 + 1.5*rand(); var beta = (rand() -0.5) * 60.0; local_weather.create_streak("Stratus (thin)",lat+get_lat(x,y+4000,phi), lon+get_lon(x,y+4000,phi), alt,500.0,10,800.0,0.25,400.0,12,2800.0,0.15,600.0,alpha+90.0+beta,tri); local_weather.create_streak("Stratus (thin)",lat+get_lat(x,y-4000,phi), lon+get_lon(x,y-4000,phi), alt,500.0,10,800.0,0.25,400.0,12,2800.0,0.15,600.0,alpha+270.0+beta,tri); } var create_4_8_sstratus_undulatus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_structured"];} var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 5000; var y = 2.0 * (rand()-0.5) * 5000; var tri = 1 + 1.5*rand(); var beta = (rand() -0.5) * 60.0; local_weather.create_streak("Stratus (structured)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,500.0,20,900.0,0.25,400.0,12,2800.0,0.15,600.0,alpha+90.0+beta,tri); } var create_4_8_cirrocumulus_bank = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - 300.0;} var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 5000; var y = 2.0 * (rand()-0.5) * 5000; var tri = 1.5 + 1.5 *rand(); var beta = (rand() -0.5) * 60.0; local_weather.create_streak("Cirrocumulus (cloudlet)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,400.0,12,750.0,0.25,400.0,24,750.0,0.2,400.0,alpha+90.0+beta,tri); } var create_4_8_cirrocumulus_undulatus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - 300.0;} var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 5000; var y = 2.0 * (rand()-0.5) * 5000; var tri = 1.4 + 0.6 *rand(); var beta = (rand() -0.5) * 60.0; local_weather.create_streak("Cirrocumulus (cloudlet)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,400.0,25,300.0,0.0,900.0,15,1400.0,0.0,300.0,alpha+90.0+beta,tri); } var create_4_8_cirrocumulus_streaks = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - 300.0;} var phi = alpha * math.pi/180.0; var beta = 90.0 + (rand() -0.5) * 30.0; for (var i=0; i<2; i=i+1) { var x = 2.0 * (rand()-0.5) * 12000; var y = 2.0 * (rand()-0.5) * 12000; var tri = 1.5 + rand() * 1.5; local_weather.create_streak("Cirrocumulus (cloudlet)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,10,700.0,0.1,400.0,30,700.0,0.1,400.0,alpha+beta,tri); } } var create_4_8_altocumulus_perlucidus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - 300.0;} var phi = alpha * math.pi/180.0; for (var i=0; i<20; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Altocumulus perlucidus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,4,1400.0,0.1,900.0,4,1400.0,0.1,900.0,alpha+beta,1.0); } } var create_4_8_alttstratus_streaks = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_alt"];} var phi = alpha * math.pi/180.0; for (var i=0; i<10; i=i+1) { var x = 2.0 * (rand()-0.5) * 15000; var y = 2.0 * (rand()-0.5) * 15000; var beta = (rand() -0.5) * 20.0; var m = 20 + int(rand() * 20); var n = 3 + int(rand() * 3); local_weather.create_streak("Cirrocumulus (cloudlet)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,600.0,m,550.0,0.0,700.0,n,550.0,0.0,450.0,alpha+beta+90,1.0); } } var create_4_8_alttstratus_patches = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_alt"];} var phi = alpha * math.pi/180.0; for (var i=0; i<14; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Cirrocumulus (cloudlet)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,600.0,10,550.0,0.0,250.0,8,550.0,0.0,250.0,alpha+beta,1.0); } } var create_4_8_stratocumulus = func (lat, lon, alt, alpha) { if (local_weather.detailed_clouds_flag == 1) { create_detailed_stratocumulus_bank(lat, lon, alt, alpha); } else { create_stratocumulus_bank(lat, lon, alt, alpha); } } var create_2_8_stratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus"];} var phi = alpha * math.pi/180.0; for (var i=0; i<8; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Stratus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,5,900.0,0.2,500.0,7,900.0,0.2,500.0,alpha+beta,1.0); } } var create_2_8_tstratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_thin"];} var phi = alpha * math.pi/180.0; for (var i=0; i<8; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Stratus (thin)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,5,900.0,0.2,500.0,7,900.0,0.2,500.0,alpha+beta,1.0); } } var create_2_8_sstratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_structured"];} var phi = alpha * math.pi/180.0; for (var i=0; i<8; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Stratus (structured)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,5,900.0,0.2,500.0,7,900.0,0.2,500.0,alpha+beta,1.0); } } var create_2_8_sstratus_streak = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_structured"];} var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 6000; var y = 2.0 * (rand()-0.5) * 6000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Stratus (structured)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,100.0,20,1800.0,0.1,500.0,5,1700.0,0.0,500.0,alpha+beta,1.2); } var create_2_8_cirrostratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Cirrostratus"];} var phi = alpha * math.pi/180.0; for (var i=0; i<3; i=i+1) { var x = 2.0 * (rand()-0.5) * 12000; var y = 2.0 * (rand()-0.5) * 12000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Cirrostratus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,4,2300.0,0.2,600.0,4,2300.0,0.2,600.0,alpha+beta,1.0); } } var create_2_8_cirrocumulus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - 300.0;} var phi = alpha * math.pi/180.0; for (var i=0; i<25; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Cirrocumulus (cloudlet)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,300.0,3,600.0,0.1,500.0,3,600.0,0.1,500.0,alpha+beta,1.0); } } var create_2_8_cirrus = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 1000; var y = 2.0 * (rand()-0.5) * 1000; local_weather.create_streak("Cirrus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,1500.0,2,20000.0,0.0, 3000.0, 2,20000.0,0.0,3000.0,alpha,1.0); } var create_2_8_alttstratus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Stratus_alt"];} var phi = alpha * math.pi/180.0; for (var i=0; i<4; i=i+1) { var x = 2.0 * (rand()-0.5) * 18000; var y = 2.0 * (rand()-0.5) * 18000; var beta = (rand() -0.5) * 180.0; local_weather.create_streak("Cirrocumulus (cloudlet)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,600.0,10,550.0,0.0,250.0,8,550.0,0.0,250.0,alpha+beta,1.0); } } var create_2_8_altocumulus_streaks = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; for (var i=0; i<2; i=i+1) { var x = 2.0 * (rand()-0.5) * 10000; var y = 2.0 * (rand()-0.5) * 10000; var tri = 1.0 + rand(); local_weather.create_streak("Altocumulus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,1500.0,22,750.0,0.2,1000.0,8,750.0,0.2,1000.0,alpha ,tri); } } var create_1_8_altocumulus_scattered = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; local_weather.create_streak("Altocumulus",lat, lon, alt,1500.0,15,0.0,0.2,19000.0,15,0.0,0.2,19000.0,alpha ,0.0); for (var i=0; i<6; i=i+1) { var x = 2.0 * (rand()-0.5) * 14000; var y = 2.0 * (rand()-0.5) * 14000; var tri = 1.0 + rand(); local_weather.create_streak("Altocumulus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,1500.0,10,750.0,0.1,800.0,4,550.0,0.1,500.0,alpha ,tri); } } var create_1_8_cirrocumulus = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; for (var i = 0; i < 2; i = i + 1) { var x = 2.0 * (rand()-0.5) * 10000; var y = -6000 + i * 12000 + 2.0 * (rand()-0.5) * 1000; var beta = rand() * 90; var alt_variation = rand() * 2000; var path = local_weather.select_cloud_model("Cirrocumulus", "large"); compat_layer.create_cloud(path, lat + get_lat(x,y,phi), lon+get_lon(x,y,phi), alt + alt_variation,alpha+ beta); } } var create_1_8_cirrus = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 2000; var y = 2.0 * (rand()-0.5) * 2000; local_weather.create_streak("Cirrus",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,1500.0,1,24000.0,0.0, 9000.0, 2,24000.0,0.0,4000.0,alpha,1.0); } var create_1_8_cirrostratus_undulatus = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - local_weather.offset_map["Cirrostratus"];} local_weather.create_undulatus("Cirrostratus",lat, lon, alt,300.0,1,8000.0,0.0,400.0,40,1000.0,0.1,100.0, 1500.0, alpha,1.0); } var create_1_8_contrails = func (lat, lon, alt, alpha) { if (local_weather.hardcoded_clouds_flag == 1) {alt = alt - 300.0;} var phi = alpha * math.pi/180.0; var n_contrails = int(rand() * 3.0) + 1; for (var i=0; i 0.6) {create_medium_thunderstorm(lat +get_lat(x,y,phi), lon + get_lon(x,y,phi), alt, alpha);} else {create_small_thunderstorm(lat +get_lat(x,y,phi), lon + get_lon(x,y,phi), alt, alpha);} if (rand() > 0.5) # we do a second thunderstorm { x = 2.0 * (rand()-0.5) * 12000; y = 2.0 * (rand()-0.5) * 12000; if (rand() > 0.8) {create_medium_thunderstorm(lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt, alpha);} else {create_small_thunderstorm(lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt, alpha);} } # the convective layer var strength = 0.3; var n = int(4000 * strength) * 0.5; local_weather.cumulus_exclusion_layer(lat, lon, alt, n, 20000.0, 20000.0, alpha, 0.3,2.5 , size(elat), elat, elon, erad); # some turbulence in the convection layer local_weather.create_effect_volume(3, lat, lon, 20000.0, 20000.0, alpha, 0.0, alt+3000.0, -1, -1, -1, 0.4, -1,0 ,-1); } var create_stratocumulus_bank = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 10000; var y = 2.0 * (rand()-0.5) * 10000; var tri = 1.5 + 1.5*rand(); var beta = (rand() -0.5) * 60.0; local_weather.create_streak("Cumulus",lat+get_lat(x,y+6000,phi), lon+get_lon(x,y+6000,phi), alt,500.0,15,600.0,0.2,400.0,20,600.0,0.2,400.0,alpha+90.0+beta,tri); local_weather.create_streak("Cumulus",lat+get_lat(x,y-6000,phi), lon+get_lon(x,y-6000,phi), alt,500.0,15,600.0,0.2,400.0,20,600.0,0.2,400.0,alpha+270.0+beta,tri); } var create_detailed_stratocumulus_bank = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 6000; var y = 2.0 * (rand()-0.5) * 6000; var tri = 1.5 + 1.5*rand(); var beta = (rand() -0.5) * 60.0; var m = int(7 + rand() * 7); var n = int(9 + rand() * 7); var alt_offset = 0.5 * local_weather.cloud_vertical_size_map["Cumulus"] * ft_to_m; if (local_weather.hardcoded_clouds_flag == 0) { local_weather.create_streak("Stratocumulus",lat+get_lat(x,y+7500,phi), lon+get_lon(x,y+7500,phi), alt + alt_offset,500.0,m,1100.0,0.1,400.0,n,1100.0,0.1,400.0,alpha+90.0+beta,tri); local_weather.create_streak("Stratocumulus",lat+get_lat(x,y-7500,phi), lon+get_lon(x,y-7500,phi), alt + alt_offset,500.0,m,1100.0,0.1,400.0,n,1100.0,0.1,400.0,alpha+270.0+beta,tri); local_weather.create_streak("Stratocumulus bottom",lat+get_lat(x,y+5250,phi), lon+get_lon(x,y+5250,phi), alt,0.0,m+1,700.0,0.2,400.0,n+1,700.0,0.0,400.0,alpha+90.0+beta,tri); local_weather.create_streak("Stratocumulus bottom",lat+get_lat(x,y-5250,phi), lon+get_lon(x,y-5250,phi), alt,0.0,m+1,700.0,0.2,400.0,n+1,700.0,0.0,400.0,alpha+270.0+beta,tri); } else { local_weather.create_streak("Stratocumulus",lat+get_lat(x,y+7500,phi), lon+get_lon(x,y+7500,phi), alt-1000.0 ,500.0,m,1100.0,0.1,400.0,n,1100.0,0.1,400.0,alpha+90.0+beta,tri); local_weather.create_streak("Stratocumulus",lat+get_lat(x,y-7500,phi), lon+get_lon(x,y-7500,phi), alt-1000.0 ,500.0,m,1100.0,0.1,400.0,n,1100.0,0.1,400.0,alpha+270.0+beta,tri); local_weather.create_streak("Stratocumulus bottom",lat+get_lat(x,y+5250,phi), lon+get_lon(x,y+5250,phi), alt-1000.0,0.0,m+1,700.0,0.2,400.0,n+1,700.0,0.0,400.0,alpha+90.0+beta,tri); local_weather.create_streak("Stratocumulus bottom",lat+get_lat(x,y-5250,phi), lon+get_lon(x,y-5250,phi), alt-1000.0,0.0,m+1,700.0,0.2,400.0,n+1,700.0,0.0,400.0,alpha+270.0+beta,tri); } } var create_detailed_small_stratocumulus_bank = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; var x = 2.0 * (rand()-0.5) * 12000; var y = 2.0 * (rand()-0.5) * 12000; var tri = 1.5 + 1.5*rand(); var beta = (rand() -0.5) * 60.0; var m = int(5 + rand() * 5); var n = int(6 + rand() * 5); var alt_offset = 0.5 * local_weather.cloud_vertical_size_map["Cumulus"] * ft_to_m; local_weather.create_streak("Stratocumulus",lat+get_lat(x,y+7500,phi), lon+get_lon(x,y+7500,phi), alt + alt_offset,500.0,m,1100.0,0.12,400.0,n,1100.0,0.12,400.0,alpha+90.0+beta,tri); local_weather.create_streak("Stratocumulus",lat+get_lat(x,y-7500,phi), lon+get_lon(x,y-7500,phi), alt + alt_offset,500.0,m,1100.0,0.12,400.0,n,1100.0,0.12,400.0,alpha+270.0+beta,tri); local_weather.create_streak("Stratocumulus bottom",lat+get_lat(x,y+7050,phi), lon+get_lon(x,y+7050,phi), alt,0.0,m,700.0,0.2,400.0,n,700.0,0.0,400.0,alpha+90.0+beta,tri); local_weather.create_streak("Stratocumulus bottom",lat+get_lat(x,y-7050,phi), lon+get_lon(x,y-7050,phi), alt,0.0,m,700.0,0.2,400.0,n,700.0,0.0,400.0,alpha+270.0+beta,tri); } var create_cloud_bank = func (type, lat, lon, alt, x1, x2, height, n, alpha) { local_weather.create_streak(type,lat,lon, alt+ 0.5* height,height,n,0.0,0.0,x1,1,0.0,0.0,x2,alpha,1.0); } var create_small_thunderstorm = func(lat, lon, alt, alpha) { var scale = 0.7 + rand() * 0.3; var alt_eff = alt; if (local_weather.hardcoded_clouds_flag == 1) {alt_eff = alt - local_weather.offset_map["Stratus"] - 2000.0; } local_weather.create_layer("Stratus", lat, lon, alt_eff, 1000.0, 4000.0 * scale, 4000.0 * scale, 0.0, 1.0, 0.3, 1, 1.0); local_weather.create_layer("Cumulonimbus (cloudlet)", lat, lon, alt_eff+3000.0, 12000.0, 3000.0 * scale, 3000.0 * scale, 0.0, 2.0, 0.0, 0, 0.0); # set the exclusion region for the Cumulus layer append(elat, lat); append(elon, lon); append(erad, 4000.0 * scale * 1.2); # set precipitation, visibility, updraft and turbulence in the cloud local_weather.create_effect_volume(1, lat, lon, 4000.0 * 0.7 * scale, 4000.0 * 0.7 * scale , 0.0, 0.0, 20000.0, 600.0, 0.8, -1, 0.6, 15.0,1 ,-1); } var create_medium_thunderstorm = func(lat, lon, alt, alpha) { var scale = 0.7 + rand() * 0.3; var alt_eff = alt; if (local_weather.hardcoded_clouds_flag == 1) {alt_eff = alt - local_weather.offset_map["Nimbus"] - 2000.0; } local_weather.create_layer("Nimbus", lat, lon, alt_eff, 500.0, 6000.0 * scale, 6000.0 * scale, 0.0, 1.0, 0.3, 1, 1.5); #local_weather.create_layer("Stratus", lat, lon, alt_eff+1500, 1000.0, 5500.0 * scale, 5500.0 * scale, 0.0, 1.0, 0.3, 0, 0.0); local_weather.create_hollow_layer("Stratus", lat, lon, alt_eff+1500, 1000.0, 5500.0 * scale, 5500.0 * scale, 0.0, 1.0, 0.3, 0.5); local_weather.create_layer("Fog (thick)", lat, lon, alt_eff+4000, 6000.0, 3400.0 * scale, 3400.0 * scale, 0.0, 1.5, 0.3, 0, 0.0); local_weather.create_layer("Cumulonimbus (cloudlet)", lat, lon, alt_eff+10000, 10000.0, 3600.0 * scale, 3600.0 * scale, 0.0, 1.2, 0.0, 0, 0.0); # set the exclusion region for the Cumulus layer append(elat, lat); append(elon, lon); append(erad, 6000.0 * scale * 1.2); # set precipitation, visibility, updraft and turbulence in the cloud local_weather.create_effect_volume(1, lat, lon, 6000.0 * 0.7 * scale, 6000.0 * 0.7 * scale , 0.0, 0.0, 20000.0, 500.0, 1.0, -1, 0.8, 20.0,1,-1 ); } var create_big_thunderstorm = func(lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; var scale = 0.8; var alt_eff = alt; if (local_weather.hardcoded_clouds_flag == 1) {alt_eff = alt - local_weather.offset_map["Nimbus"]; } local_weather.create_layer("Nimbus", lat, lon, alt_eff, 500.0, 7500.0 * scale, 7500.0 * scale, 0.0, 1.0, 0.25, 1, 1.5); #local_weather.create_layer("Stratus", lat, lon, alt+1500, 1000.0, 7200.0 * scale, 7200.0 * scale, 0.0, 1.0, 0.3, 0, 0.0); local_weather.create_hollow_layer("Stratus", lat, lon, alt_eff+1500, 1000.0, 7200.0 * scale, 7200.0 * scale, 0.0, 1.0, 0.3, 0.7); local_weather.create_layer("Fog (thick)", lat, lon, alt_eff+5000, 3000.0, 5500.0 * scale, 5500.0 * scale, 0.0, 0.7, 0.3, 0, 0.0); local_weather.create_layer("Fog (thick)", lat+get_lat(0,-1000,phi), lon+get_lon(0,-1000,phi), alt_eff+12000, 4000.0, 6300.0 * scale, 6300.0 * scale, 0.0, 0.7, 0.3, 0, 0.0); #local_weather.create_layer("Stratus", lat+get_lat(0,-2000,phi), lon+get_lon(0,-2000,phi), alt+17000, 1000.0, 7500.0 * scale, 7500.0 * scale, 0.0, 1.0, 0.3, 0, 0.0); local_weather.create_hollow_layer("Stratus", lat+get_lat(0,-2000,phi), lon+get_lon(0,-2000,phi), alt_eff+17000, 1000.0, 7500.0 * scale, 7500.0 * scale, 0.0, 1.0, 0.3, 0.5); #local_weather.create_layer("Stratus", lat+get_lat(0,-3000,phi), lon+get_lon(0,-3000,phi), alt_eff+20000, 1000.0, 9500.0 * scale, 9500.0 * scale, 0.0, 1.0, 0.3, 0, 0.0); local_weather.create_hollow_layer("Stratus", lat+get_lat(0,-3000,phi), lon+get_lon(0,-3000,phi), alt_eff+20000, 1000.0, 9500.0 * scale, 9500.0 * scale, 0.0, 1.0, 0.3, 0.5); local_weather.create_layer("Stratus (thin)", lat+get_lat(0,-4000,phi), lon+get_lon(0,-4000,phi), alt_eff+24000, 1000.0, 11500.0 * scale, 11500.0 * scale, 0.0, 2.0, 0.0, 0, 0.0); # set the exclusion region for the Cumulus layer append(elat, lat); append(elon, lon); append(erad, 7500.0 * scale * 1.2); local_weather.create_effect_volume(1, lat, lon, 7500.0 * 0.7 * scale, 7500.0 * 0.7 * scale , 0.0, 0.0, 20000.0, 500.0, 1.0, -1, 1.0, 25.0,1,-1 ); } # spectacular, but not useful in practice var create_2_8_cirrocumulus_patches = func (lat, lon, alt, alpha) { var phi = alpha * math.pi/180.0; for (var i=0; i<2; i=i+1) { var x = 2.0 * (rand()-0.5) * 10000; var y = 2.0 * (rand()-0.5) * 10000; var tri = 1.5 + rand(); var beta = rand() * math.pi; #local_weather.create_streak("Cirrocumulus (new)",lat+get_lat(x,y,phi), lon+get_lon(x,y,phi), alt,0.0,50,150.0,0.2,50.0,50,150.0,0.2,50.0,alpha ,tri); local_weather.create_layer("Cirrocumulus (new)", lat+get_lat(x,y,phi), lon+get_lat(x,y,phi), alt, 0.0, 8500.0, 5000.0, beta, 15.0, 0.25, 0, 0.0); } } ################### # helper functions ################### var calc_geo = func(clat) { lon_to_m = math.cos(clat*math.pi/180.0) * lat_to_m; m_to_lon = 1.0/lon_to_m; } var get_lat = func (x,y,phi) { return (y * math.cos(phi) - x * math.sin(phi)) * m_to_lat; } var get_lon = func (x,y,phi) { return (x * math.cos(phi) + y * math.sin(phi)) * m_to_lon; } var get_n = func(strength) { return int(4000 * strength); } ################################## # continuity condition of pressure ################################## var adjust_p = func (p) { if (last_pressure == 0.0) {last_pressure = p; return p;} var pressure_difference = p - last_pressure; if (pressure_difference > 2.0) {var pout = last_pressure + 3.0;} else if (pressure_difference < -2.0) {var pout = last_pressure - 3.0;} else {var pout = p;} last_pressure = pout; return pout; } ################### # global variables ################### var lat_to_m = 110952.0; # latitude degrees to meters var m_to_lat = 9.01290648208234e-06; # meters to latitude degrees var ft_to_m = 0.30480; var m_to_ft = 1.0/ft_to_m; var inhg_to_hp = 33.76389; var hp_to_inhg = 1.0/inhg_to_hp; var last_pressure = 0.0; var lon_to_m = 0.0; # needs to be calculated dynamically var m_to_lon = 0.0; # we do this on startup var lw = "/local-weather/"; var realistic_visibility_multiplyer = 1.5; var small_scale_persistence = getprop(lw~"config/small-scale-persistence"); var rnd_store = rand(); var elat = []; var elon = []; var erad = [];