Python: improve speed interpolation technique using matplotlib natgrid toolkit with a huge amount of points

i am using matplotlib natgrid toolkit to interoplate x,y,z points. My dataset is more than 5 milion of points. I tried my code using a small area (about 900.000,00 points). Using natgrid the time is 44 minute.

Some people know a way to increase the speed or another method more efficent in term of time? for 2d interpolation there are too many data points to interpolate

thanks in advance for helps and suggestions

``````import shapefile #
import os #
import glob #
import math #
import numpy #
import numpy as np #
import matplotlib.nxutils as nx #
import collections
import matplotlib.pyplot as plt
import matplotlib.mlab as ml
import matplotlib.delaunay
from liblas import file as lasfile #
from shapely.geometry import Polygon #
from osgeo import gdal, osr, ogr #
from gdalconst import * #
from matplotlib.mlab import griddata
from collections import OrderedDict

def LAS2DTM(inFile,outFile,gridSize=1,dtype="GDT_Float32",nodata=-9999.00,BBOX=None,EPSG=None):
if BBOX == None:
X = []
Y = []
for p in lasfile.File(inFile,None,'r'):
X.append(p.x)
Y.append(p.y)
xmax, xmin = max(X),min(X)
ymax, ymin = max(Y), min(Y)
del X,Y
else:
xmax,xmin,ymax,ymin = BBOX[0],BBOX[1],BBOX[2],BBOX[3]
# number of row and columns
nx = int(math.ceil(abs(xmax - xmin)/gridSize))
ny = int(math.ceil(abs(ymax - ymin)/gridSize))
# Create an array to hold the number of points in each pixel
cnts = np.zeros((ny, nx))
# Create an array to hold the values
data = np.zeros((ny, nx))
x = []
y = []
z = []
for p in lasfile.File(inFile,None,'r'):
x.append(p.x)
y.append(p.y)
z.append(p.z)
# Compute the x and y offsets for where this point would be in the raster
dx = int((p.x - xmin)/gridSize)
dy = int((ymax - p.y)/gridSize)
# Add the z value to the total for that pixel
data[dy,dx] += p.z
# Add 1 to our count for that pixel
cnts[dy,dx] += 1
# ingore Error message
np.seterr(invalid='ignore')
# Compute the averages
data = data/cnts
del cnts
# remove all duplicate points from a X,Y,Z file that have identical x and y coordinates
# The first point survives, all subsequent duplicates are removed.
tmp = OrderedDict()
for point in zip(x, y, z):
a = tmp.setdefault(point[:2], point)
mypoints = tmp.values()
del x,y,z
points_zipped = zip(*mypoints)
del mypoints
xvals = np.array(points_zipped[0])
yvals = np.array(points_zipped[1])
zvals = np.array(points_zipped[2])
del points_zipped
# define grid.
xi = np.linspace(xmin, xmax, nx)
yi = np.linspace(ymin, ymax, ny)
# create a meshgrid
xi, yi = np.meshgrid(xi, yi)
# grid the data.
zi = griddata(xvals,yvals,zvals,xi,yi,interp='nn')
# convert "numpy.ma.core.MaskedArray" in a "np.array"
zi = np.array(zi)
# mask a numpy.ndarray with another numpy.ndarray
data[np.isnan(data)] = zi[np.isnan(data)]
# Create gtif
if dtype == "GDT_Unknown": # Unknown or unspecified type
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_Unknown)
elif dtype == "GDT_Byte": # Eight bit unsigned integer
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_Byte)
elif dtype == "GDT_UInt16": # Sixteen bit unsigned integer
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_UInt16)
elif dtype == "GDT_Int16": # Sixteen bit signed integer
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_Int16)
elif dtype == "GDT_UInt32": # Thirty two bit unsigned integer
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_UInt32)
elif dtype == "GDT_Int32": # Thirty two bit signed integer
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_Int32)
elif dtype == "GDT_Float32": # Thirty two bit floating point
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_Float32)
elif dtype == "GDT_Float64": # Sixty four bit floating point
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_Float64)
elif dtype == "GDT_CInt16": # Complex Int16
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_CInt16)
elif dtype == "GDT_CInt32": # Complex Int32
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_CInt32)
elif dtype == "GDT_CFloat32": # Complex Float32
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_CFloat32)
elif dtype == "GDT_CFloat64": # Complex Float64
target_ds = gdal.GetDriverByName('GTiff').Create(outFile, nx,ny, 1, gdal.GDT_CFloat64)
# top left x, w-e pixel resolution, rotation, top left y, rotation, n-s pixel resolution
target_ds.SetGeoTransform((xmin, gridSize, 0,ymax, 0, -gridSize))
# set the reference info
if EPSG is None:
# Source has no projection (needs GDAL >= 1.7.0 to work)
target_ds.SetProjection('LOCAL_CS["arbitrary"]')
else:
proj = osr.SpatialReference()
proj.ImportFromEPSG(EPSG)
# Make the target raster have the same projection as the source
target_ds.SetProjection(proj.ExportToWkt())
# write the band
target_ds.GetRasterBand(1).WriteArray(data)
target_ds.GetRasterBand(1).SetNoDataValue(nodata)
target_ds = None
``````
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