538 lines
14 KiB
Text
538 lines
14 KiB
Text
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########################################################
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# routines to simulate cloud wind drift and evolution
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# Thorsten Renk, July 2010
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########################################################
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# function purpose
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#
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# get_windfield to get the current wind in the tile
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# timing_loop to provide accurate timing information for wind drift calculations
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# quadtree_loop to manage drift of clouds in the field of view
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# weather_dynamics_loop to manage drift of weather effects, tile centers and interpolation points
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# generate_quadtree_structure to generate a quadtree data structure used for managing the visual field
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# sort_into_quadtree to sort objects into a quadtree structure
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# quadtree_recursion to search the quadtree for objects in the visual field
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# check_visibility to check if a quadrant is currently visible
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# move_tile to move tile coordinates in the wind
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# move_effect_volume to move an effect volume in the wind
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# move_weather_station to move a weather station in the wind
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# get_cartesian to get local Cartesian coordinates out of coordinates
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####################################################
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# get the windfield for a given locatio and altitude
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# (currently constant, but supposed to be local later)
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####################################################
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var get_windfield = func (tile_index) {
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var windfield = [];
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if ((local_weather.wind_model_flag == 1) or (local_weather.wind_model_flag == 3))
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{
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var windspeed = tile_wind_speed[0] * kt_to_ms;
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var wind_direction = tile_wind_direction[0];
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}
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else if ((local_weather.wind_model_flag ==2) or (local_weather.wind_model_flag == 4) or (local_weather.wind_model_flag == 5))
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{
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var windspeed = tile_wind_speed[tile_index-1] * kt_to_ms;
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var wind_direction = tile_wind_direction[tile_index-1];
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}
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var windfield_x = -windspeed * math.sin(wind_direction * math.pi/180.0);
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var windfield_y = -windspeed * math.cos(wind_direction * math.pi/180.0);
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append(windfield,windfield_x);
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append(windfield,windfield_y);
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return windfield;
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}
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########################################################
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# timing loop
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# this gets the accurate time since the start of weather dynamics
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# and hence the timestamps for cloud evolution since
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# the available elapsed-time-sec is not accurate enough
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########################################################
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var timing_loop = func {
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time_lw = time_lw + getprop("/sim/time/delta-sec");
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if (getprop(lw~"timing-loop-flag") ==1) {settimer(timing_loop, 0);}
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}
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###########################################################
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# quadtree loop
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# the quadtree loop is a fast loop updating the position
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# of visible objects in the field of view only
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###########################################################
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var quadtree_loop = func {
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var vangle = 0.55 * getprop("/sim/current-view/field-of-view");
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var viewdir = getprop("/sim/current-view/goal-heading-offset-deg");
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var lat = getprop("position/latitude-deg");
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var lon = getprop("position/longitude-deg");
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var course = getprop("orientation/heading-deg");
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cloud_counter = 0;
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# pre-calculate trigonometry
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tan_vangle = math.tan(vangle * math.pi/180.0);
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# use the quadtree to move clouds inside the field of view
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var tiles = props.globals.getNode(lw~"tiles").getChildren("tile");
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foreach (t; tiles)
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{
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var generated_flag = t.getNode("generated-flag").getValue();
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if (generated_flag == 1)
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{
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var index = t.getNode("tile-index").getValue();
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current_tile_index_wd = index;
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var blat = t.getNode("latitude-deg").getValue();
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var blon = t.getNode("longitude-deg").getValue();
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var alpha = t.getNode("orientation-deg").getValue();
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var xy_vec = get_cartesian(blat, blon, alpha, lat, lon);
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var beta = course - alpha - viewdir ;
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cos_beta = math.cos(beta * math.pi/180.0);
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sin_beta = math.sin(beta * math.pi/180.0);
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plane_x = xy_vec[0]; plane_y = xy_vec[1];
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quadtree_recursion(cloudQuadtrees[index-1],0,1,0.0,0.0);
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}
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}
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# dynamically adjust the range of the processed view field
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# if there are plenty of moving clouds nearby, no one pays attention to the small motion of distant clouds
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# price to pay is that some clouds appear to jump once they get into range
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if (cloud_counter < 150) {view_distance = view_distance * 1.1;}
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else if (cloud_counter > 250) {view_distance = view_distance * 0.9;}
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if (view_distance > 30000.0) {view_distance = 30000.0;}
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#print(cloud_counter, " ", view_distance/1000.0);
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# shift the tile centers with the windfield
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var tiles = props.globals.getNode("local-weather/tiles", 1).getChildren("tile");
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foreach (t; tiles) {move_tile(t);}
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# loop over
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if (getprop(lw~"dynamics-loop-flag") ==1) {settimer(quadtree_loop, 0);}
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}
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###########################################################
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# weather_dynamics_loop
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# the weather dynamics loop is a slow loop updating
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# position and state of invisible objects, currently
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# effect volumes and weather stations
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###########################################################
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var weather_dynamics_loop = func (index) {
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var n = 20;
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var i_max = index + n;
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if (i_max > local_weather.n_effectVolumeArray) {i_max = local_weather.n_effectVolumeArray;}
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for (var i = index; i < i_max; i = i+1)
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{
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move_effect_volume(local_weather.effectVolumeArray[i]);
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}
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index = index + n;
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if (i >= local_weather.n_effectVolumeArray) {index = 0;}
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var stations = props.globals.getNode(lw~"interpolation").getChildren("station");
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foreach (s; stations)
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{
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move_weather_station(s);
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}
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if (getprop(lw~"dynamics-loop-flag") ==1) {settimer( func {weather_dynamics_loop(index); },0);}
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}
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###########################################################
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# generate quadtree structure
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###########################################################
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var generate_quadtree_structure = func (depth, tree_base_vec) {
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var c_vec = [];
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for (var i=0; i<4; i=i+1)
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{
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if (depth == quadtree_depth)
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{var c = [];}
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else
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{var c = generate_quadtree_structure(depth+1, tree_base_vec);}
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if (depth==0)
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{append(tree_base_vec,c); }
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else
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{append(c_vec,c); }
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}
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if (depth ==0) {return tree_base_vec;} else {return c_vec;}
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}
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###########################################################
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# sort into quadtree
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###########################################################
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var sort_into_quadtree = func (blat, blon, alpha, lat, lon, tree, object) {
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xy_vec = get_cartesian (blat, blon, alpha, lat, lon);
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sorting_recursion (xy_vec[0], xy_vec[1], tree, object, 0);
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}
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var sorting_recursion = func (x, y, tree, object, depth) {
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if (depth == quadtree_depth+1) {append(tree,object); return;}
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var length_scale = 20000.0 / math.pow(2,depth);
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# print("depth: ", depth, "x: ", x, "y: ",y);
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if (y > 0.0)
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{
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if (x < 0.0)
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{var v = tree[0]; x = x + 0.5 * length_scale; y = y - 0.5 * length_scale;}
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else
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{var v = tree[1]; x = x - 0.5 * length_scale; y = y - 0.5 * length_scale;}
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}
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else
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{
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if (x < 0.0)
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{var v = tree[2]; x = x + 0.5 * length_scale; y = y + 0.5 * length_scale;}
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else
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{var v = tree[3]; x = x - 0.5 * length_scale; y = y + 0.5 * length_scale;}
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}
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sorting_recursion(x, y, v, object, depth+1);
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}
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####################################################
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# quadtree recursive search
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####################################################
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var quadtree_recursion = func (tree, depth, flag, qx, qy) {
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# flag = 0: quadrant invisible, stop search
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# flag = 1: quadrant partially visible, continue search with visibility tests
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# flag = 2: quadrant fully visible, no further visibility test needed
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if (depth == quadtree_depth +1)
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{
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foreach (var c; tree)
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{
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compat_layer.move_cloud(c, current_tile_index_wd);
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cloud_counter = cloud_counter + 1;
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}
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return;
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}
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for (var i =0; i<4; i=i+1)
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{
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if (flag==2) {quadtree_recursion(tree[i], depth+1, flag, qx, qy);}
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else if (flag==1)
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{
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# compute the subquadrant coordinates
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var length_scale = 20000.0 / math.pow(2,depth);
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if (i==0) {var qxnew = qx - 0.5 * length_scale; var qynew = qy + 0.5 * length_scale;}
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else if (i==1) {var qxnew = qx + 0.5 * length_scale; var qynew = qy + 0.5 * length_scale;}
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else if (i==2) {var qxnew = qx - 0.5 * length_scale; var qynew = qy - 0.5 * length_scale;}
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else if (i==3) {var qxnew = qx + 0.5 * length_scale; var qynew = qy - 0.5 * length_scale;}
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var newflag = check_visibility(qxnew,qynew, length_scale);
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if (newflag!=0) {quadtree_recursion(tree[i], depth+1, newflag, qxnew, qynew);}
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}
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}
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}
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####################################################
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# quadrant visibility test
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####################################################
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var check_visibility = func (qx,qy, length_scale) {
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# (qx,qy) are the quadrant coordinates in tile local Cartesian
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# beta is the plane course in the tile local Cartesian
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# the function returns a flag: 0: invisible 1: partially visible, track further 2: fully visible
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# first translate/rotate (qx,qy) into the plane system
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qx = qx - plane_x; qy = qy - plane_y;
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var x = qx * cos_beta - qy * sin_beta;
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var y = qy * cos_beta + qx * sin_beta;
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# now get the maximum and minimum quadrant extensions
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var ang_factor = abs(cos_beta) + abs(sin_beta); # a square seen from an angle extends larger
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var xmax = x + 0.5 * length_scale * ang_factor;
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var xmin = x - 0.5 * length_scale * ang_factor;
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var ymax = y + 0.5 * length_scale * ang_factor;
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var ymin = y - 0.5 * length_scale * ang_factor;
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# now do visibility checks
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if ((ymax < 0.0) and (ymin < 0.0)) # quadrant is behind us, we can never see it
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{return 0;}
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if (ymin > view_distance) # the quadrant is beyond visible range
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{return 0;}
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var xcomp_min = ymin * tan_vangle;
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var xcomp_max = ymax * tan_vangle;
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if ((ymax > 0.0) and (ymin < 0.0)) # object is at most partially visible, check if in visual cone at ymax
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{
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if ((xmax < -xcomp_max) and (xmin < -xcomp_max)) {return 0;}
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if ((xmax > xcomp_max) and (xmin > xcomp_max)) {return 0;}
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return 1;
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}
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# now we know the quadrant must be in front
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# check if invisible
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if ((xmax < -xcomp_max) and (xmin < -xcomp_max)) {return 0;}
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if ((xmax > xcomp_max) and (xmin > xcomp_max)) {return 0;}
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# check if completely visible
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if ((xmax > -xcomp_min) and (xmin > -xcomp_min) and (xmax < xcomp_min) and (xmin < xcomp_min))
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{return 2;}
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# at this point, it must be partially visible
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return 1;
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}
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####################################################
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# move a tile
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####################################################
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var move_tile = func (t) {
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# get the old spacetime position of the tile
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var lat_old = t.getNode("latitude-deg").getValue();
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var lon_old = t.getNode("longitude-deg").getValue();
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var timestamp = t.getNode("timestamp-sec").getValue();
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var tile_index = t.getNode("tile-index").getValue();
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# if the tile is not yet generated, we use the windfield of the tile we're in
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if (tile_index == -1)
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{
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tile_index = props.globals.getNode(lw~"tiles").getChild("tile",4).getNode("tile-index").getValue();
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}
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# get windfield and time since last update
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var windfield = get_windfield(tile_index);
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var dt = time_lw - timestamp;
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# update the spacetime position of the tile
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t.getNode("latitude-deg",1).setValue(lat_old + windfield[1] * dt * local_weather.m_to_lat);
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t.getNode("longitude-deg",1).setValue(lon_old + windfield[0] * dt * local_weather.m_to_lon);
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t.getNode("timestamp-sec",1).setValue(weather_dynamics.time_lw);
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}
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####################################################
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# move an effect volume
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####################################################
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var move_effect_volume = func (e) {
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# get the old spacetime position of the effect
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var lat_old = e.getNode("position/latitude-deg").getValue();
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var lon_old = e.getNode("position/longitude-deg").getValue();
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var tile_index = e.getNode("tile-index").getValue();
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var timestamp = e.getNode("timestamp-sec").getValue();
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# get windfield and time since last update
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var windfield = weather_dynamics.get_windfield(tile_index);
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var dt = weather_dynamics.time_lw - timestamp;
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# update the spacetime position of the effect
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e.getNode("position/latitude-deg",1).setValue(lat_old + windfield[1] * dt * local_weather.m_to_lat);
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e.getNode("position/longitude-deg",1).setValue(lon_old + windfield[0] * dt * local_weather.m_to_lon);
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e.getNode("timestamp-sec",1).setValue(weather_dynamics.time_lw);
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}
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####################################################
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# move a weather station
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####################################################
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var move_weather_station = func (s) {
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# get the old spacetime position of the station
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var lat_old = s.getNode("latitude-deg").getValue();
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var lon_old = s.getNode("longitude-deg").getValue();
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var tile_index = s.getNode("tile-index").getValue();
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var timestamp = s.getNode("timestamp-sec").getValue();
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# get windfield and time since last update
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var windfield = weather_dynamics.get_windfield(tile_index);
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var dt = weather_dynamics.time_lw - timestamp;
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# update the spacetime position of the effect
|
||
|
|
||
|
s.getNode("latitude-deg",1).setValue(lat_old + windfield[1] * dt * local_weather.m_to_lat);
|
||
|
s.getNode("longitude-deg",1).setValue(lon_old + windfield[0] * dt * local_weather.m_to_lon);
|
||
|
s.getNode("timestamp-sec",1).setValue(weather_dynamics.time_lw);
|
||
|
}
|
||
|
|
||
|
|
||
|
###########################################################
|
||
|
# get local Cartesian coordinates
|
||
|
###########################################################
|
||
|
|
||
|
var get_cartesian = func (blat, blon, alpha, lat, lon) {
|
||
|
|
||
|
var xy_vec = [];
|
||
|
|
||
|
var phi = alpha * math.pi/180.0;
|
||
|
|
||
|
var delta_lat = lat - blat;
|
||
|
var delta_lon = lon - blon;
|
||
|
|
||
|
var x1 = delta_lon * lon_to_m;
|
||
|
var y1 = delta_lat * lat_to_m;
|
||
|
|
||
|
var x = x1 * math.cos(phi) - y1 * math.sin(phi);
|
||
|
var y = y1 * math.cos(phi) + x1 * math.sin(phi);
|
||
|
|
||
|
append(xy_vec,x);
|
||
|
append(xy_vec,y);
|
||
|
|
||
|
return xy_vec;
|
||
|
|
||
|
}
|
||
|
|
||
|
|
||
|
|
||
|
################################
|
||
|
# globals, constants, properties
|
||
|
################################
|
||
|
|
||
|
|
||
|
|
||
|
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 kt_to_ms = 0.514;
|
||
|
var ms_to_kt = 1./kt_to_ms;
|
||
|
|
||
|
var lon_to_m = 0.0; # needs to be calculated dynamically
|
||
|
var m_to_lon = 0.0; # we do this on startup
|
||
|
|
||
|
# abbreviations
|
||
|
|
||
|
var lw = "/local-weather/";
|
||
|
|
||
|
|
||
|
# globals
|
||
|
|
||
|
var time_lw = 0.0;
|
||
|
|
||
|
# the quadtree structure
|
||
|
|
||
|
var cloudQuadtrees = [];
|
||
|
var quadtree_depth = 3;
|
||
|
|
||
|
# the wind info for the individual weather tiles
|
||
|
# (used for 'constant in tile' wind model)
|
||
|
|
||
|
var tile_wind_direction = [];
|
||
|
var tile_wind_speed = [];
|
||
|
|
||
|
# define these as global, as we need to evaluate them only once per frame
|
||
|
# but use them over and over
|
||
|
|
||
|
var tan_vangle = 0;
|
||
|
var cos_beta = 0;
|
||
|
var sin_beta = 0;
|
||
|
var plane_x = 0;
|
||
|
var plane_y = 0;
|
||
|
|
||
|
var current_tile_index_wd = 0;
|
||
|
|
||
|
var cloud_counter = 0;
|
||
|
var view_distance = 30000.0;
|
||
|
|
||
|
# create the loop flags
|
||
|
|
||
|
setprop(lw~"timing-loop-flag",0);
|
||
|
setprop(lw~"dynamics-loop-flag",0);
|