I have an array of longitude-latitude points that defines the boundaries of an area. I would like to create a polygon based on these points and plot the polygon on a map and fill it. Currently, my polygon seems to consist of many patches that connect all the points, but the order of the points is not correct and when I try to fill the polygon I get a weird looking area (see attached).
I sort my longitude-latitude points (mypolyXY array) according to the center of the polygon, but my guess is that this is not correct:
cent=(np.sum([p for p in mypolyXY])/len(mypolyXY),np.sum([p for p in mypolyXY])/len(mypolyXY)) # sort by polar angle mypolyXY.sort(key=lambda p: math.atan2(p-cent,p-cent))
I plot the point locations (black circles) and my polygons (colored patches) using
scatter([p for p in mypolyXY],[p for p in mypolyXY],2) p = Polygon(mypolyXY,facecolor=colors,edgecolor='none') ax.add_artist(p)
My question is: how can I close my polygon based on my array of longitude-latitude points?
UPDATE: I tested some more on how to plot the polygon. I removed the sort routine and just used the data in the order they occur in the file. This seems to improve the result, but as @tcaswell mentioned, the polygon shape still undercuts itself (see new plot). I am hoping that there could be a path/polygon routine that could solve my problem and sort of merge all shapes or paths within the boundaries of the polygon. Suggestions are very welcome.
I have now a working version of my script that is based on suggestions by @Rutger Kassies and Roland Smith. I ended up reading the Shapefile using org which worked relatively well. It worked well for the standard lmes_64.shp file but when I used more detailed LME files where each LME could consist of several polygons this script broke down. I would have to find a way to merge the various polygons for identical LME names to make that work. I attach my script I ended up with in case anyone would take a look at it. I very much appreciate comments for how to improve this script or to make it more generic. This script creates the polygons and extracts data within the polygon region that I read from a netcdf file. The grid of the input file is -180 to 180 and -90 to 90.
import numpy as np import math from pylab import * import matplotlib.patches as patches import string, os, sys import datetime, types from netCDF4 import Dataset import matplotlib.nxutils as nx from mpl_toolkits.basemap import Basemap import ogr import matplotlib.path as mpath import matplotlib.patches as patches def getLMEpolygon(coordinatefile,mymap,index,first): ds = ogr.Open(coordinatefile) lyr = ds.GetLayer(0) numberOfPolygons=lyr.GetFeatureCount() if first is False: ft = lyr.GetFeature(index) print "Found polygon:", ft.items()['LME_NAME'] geom = ft.GetGeometryRef() codes =  all_x =  all_y =  all_XY=  if (geom.GetGeometryType() == ogr.wkbPolygon): for i in range(geom.GetGeometryCount()): r = geom.GetGeometryRef(i) x = [r.GetX(j) for j in range(r.GetPointCount())] y = [r.GetY(j) for j in range(r.GetPointCount())] codes += [mpath.Path.MOVETO] + (len(x)-1)*[mpath.Path.LINETO] all_x += x all_y += y all_XY +=mymap(x,y) if len(all_XY)==0: all_XY=None mypoly=None else: mypoly=np.empty((len(all_XY[:]),2)) mypoly[:,0]=all_XY[:] mypoly[:,1]=all_XY[:] else: print "Will extract data for %s polygons"%(numberOfPolygons) mypoly=None first=False return mypoly, first, numberOfPolygons def openCMIP5file(CMIP5name,myvar,mymap): if os.path.exists(CMIP5name): myfile=Dataset(CMIP5name) print "Opened CMIP5 file: %s"%(CMIP5name) else: print "Could not find CMIP5 input file %s : abort"%(CMIP5name) sys.exit() mydata=np.squeeze(myfile.variables[myvar][-1,:,:]) - 273.15 lonCMIP5=np.squeeze(myfile.variables["lon"][:]) latCMIP5=np.squeeze(myfile.variables["lat"][:]) lons,lats=np.meshgrid(lonCMIP5,latCMIP5) lons=lons.flatten() lats=lats.flatten() mygrid=np.empty((len(lats),2)) mymapgrid=np.empty((len(lats),2)) for i in xrange(len(lats)): mygrid[i,0]=lons[i] mygrid[i,1]=lats[i] X,Y=mymap(lons[i],lats[i]) mymapgrid[i,0]=X mymapgrid[i,1]=Y return mydata, mygrid, mymapgrid def drawMap(NUM_COLORS): ax = plt.subplot(111) cm = plt.get_cmap('RdBu') ax.set_color_cycle([cm(1.*j/NUM_COLORS) for j in range(NUM_COLORS)]) mymap = Basemap(resolution='l',projection='robin',lon_0=0) mymap.drawcountries() mymap.drawcoastlines() mymap.fillcontinents(color='grey',lake_color='white') mymap.drawparallels(np.arange(-90.,120.,30.)) mymap.drawmeridians(np.arange(0.,360.,60.)) mymap.drawmapboundary(fill_color='white') return ax, mymap, cm """Edit the correct names below:""" LMEcoordinatefile='ShapefileBoundaries/lmes_64.shp' CMIP5file='tos_Omon_CCSM4_rcp85_r1i1p1_200601-210012_regrid.nc' mydebug=False doPoints=False first=True """initialize the map:""" mymap=None mypolyXY, first, numberOfPolygons = getLMEpolygon(LMEcoordinatefile, mymap, 0,first) NUM_COLORS=numberOfPolygons ax, mymap, cm = drawMap(NUM_COLORS) """Get the CMIP5 data together with the grid""" SST,mygrid, mymapgrid = openCMIP5file(CMIP5file,"tos",mymap) """For each LME of interest create a polygon of coordinates defining the boundaries""" for counter in xrange(numberOfPolygons-1): mypolyXY,first,numberOfPolygons = getLMEpolygon(LMEcoordinatefile, mymap,counter,first) if mypolyXY != None: """Find the indices inside the grid that are within the polygon""" insideBoolean = plt.mlab.inside_poly(np.c_[mymapgrid[:,0],mymapgrid[:,1]],np.c_[mypolyXY[:,0],mypolyXY[:,1]]) SST=SST.flatten() SST=np.ma.masked_where(SST>50,SST) mymapgrid=np.c_[mymapgrid[:,0],mymapgrid[:,1]] myaverageSST=np.mean(SST[insideBoolean]) mycolor=cm(myaverageSST/SST.max()) scaled_z = (myaverageSST - SST.min()) / SST.ptp() colors = plt.cm.coolwarm(scaled_z) scatter([p for p in mypolyXY],[p for p in mypolyXY],2) p = Polygon(mypolyXY,facecolor=colors,edgecolor='none') ax.add_artist(p) if doPoints is True: for point in xrange(len(insideBoolean)): pointX=mymapgrid[insideBoolean[point],0] pointY=mymapgrid[insideBoolean[point],1] ax.scatter(pointX,pointY,8,color=colors) ax.hold(True) if doPoints is True: colorbar() print "Extracted average values for %s LMEs"%(numberOfPolygons) plt.savefig('LMEs.png',dpi=300) plt.show()
Final image attached. Thanks for all help.