36

I have a large number of polygons (~100000) and try to find a smart way of calculating their intersecting area with a regular grid cells.

Currently, I am creating the polygons and the grid cells using shapely (based on their corner coordinates). Then, using a simple for-loop I go through each polygon and compare it to nearby grid cells.

Just a small example to illustrate the polygons/grid cells.

from shapely.geometry import box, Polygon
# Example polygon 
xy = [[130.21001, 27.200001], [129.52, 27.34], [129.45, 27.1], [130.13, 26.950001]]
polygon_shape = Polygon(xy)
# Example grid cell
gridcell_shape = box(129.5, -27.0, 129.75, 27.25)
# The intersection
polygon_shape.intersection(gridcell_shape).area

(BTW: the grid cells have the dimensions 0.25x0.25 and the polygons 1x1 at max)

Actually this is quite fast for an individual polygon/grid cell combo with around 0.003 seconds. However, running this code on a huge amount of polygons (each one could intersect dozens of grid cells) takes around 15+ minutes (up to 30+ min depending on the number of intersecting grid cells) on my machine which is not acceptable. Unfortunately, I have no idea how it is possible to write a code for polygon intersection to get the area of overlap. Do you have any tips? Is there an alternative to shapely?

  • 1
    I'm curious how you are looping and intersecting your polygons. Can you show more code on the process? It would be easier to figure out how this can be optimized. – tdedecko Feb 5 '13 at 0:30
  • I basically take an array of lat/lon corner values and convert them in a for loop to the polygons. Then, I compare each polygon to certain grid cell, which is done in a for-loop again. See this: stackoverflow.com/a/13956110/1740928 – HyperCube Feb 5 '13 at 8:35
55

Consider using Rtree to help identify which grid cells that a polygon may intersect. This way, you can remove the for loop used with the array of lat/lons, which is probably the slow part.

Structure your code something like this:

from shapely.ops import cascaded_union
from rtree import index
idx = index.Index()

# Populate R-tree index with bounds of grid cells
for pos, cell in enumerate(grid_cells):
    # assuming cell is a shapely object
    idx.insert(pos, cell.bounds)

# Loop through each Shapely polygon
for poly in polygons:
    # Merge cells that have overlapping bounding boxes
    merged_cells = cascaded_union([grid_cells[pos] for pos in idx.intersection(poly.bounds)])
    # Now do actual intersection
    print poly.intersection(merged_cells).area
  • 4
    This remains an incredibly helpful answer - it should have been accepted. I had a similar problem and Rtree made the algorithm run around 5000 times faster. – Gabriel Jan 9 '16 at 11:13
  • 2
    Note that Rtree can be only used for boxes (4 points), not complex polygons. – Ikar Pohorský Feb 15 '17 at 10:58
  • For "real" polygons just add a proper actual geometry intersects? check for each bounds intersection. The rtree let's you reduce the search space and things are super fast. – bugmenot123 May 16 '18 at 11:09
  • While an old answer, this is the result that i found to remind me what object.. rtree.. If you have a complex poly, just envelope it and then check against that first before the complex one.. Will help speed things up again.+1 for simple example – Angry 84 Aug 30 '18 at 6:33
  • 1
    BTW, shapely has an R-tree implementation, as noted in the answer below: shapely.readthedocs.io/en/stable/manual.html#str-packed-r-tree – Chris Anderson Jun 11 at 19:51
16

It looks like the available The Shapely User Manual is rather out of date, but since 2013/2014, Shapely has had strtree.py with the class STRtree. I have used it and it seems to work well.

Here is a snippet from the docstring:

STRtree is an R-tree that is created using the Sort-Tile-Recursive algorithm. STRtree takes a sequence of geometry objects as initialization parameter. After initialization the query method can be used to make a spatial query over those objects.

>>> from shapely.geometry import Polygon
>>> polys = [ Polygon(((0, 0), (1, 0), (1, 1))), Polygon(((0, 1), (0, 0), (1, 0))), Polygon(((100, 100), (101, 100), (101, 101))) ]
>>> s = STRtree(polys)
>>> query_geom = Polygon(((-1, -1), (2, 0), (2, 2), (-1, 2)))
>>> result = s.query(query_geom)
>>> polys[0] in result
True
  • This is so helpfull. Do you know if the STRtree can be serialized with pickle or marshall libraries to save it for later use? – eguaio Aug 30 '17 at 22:25
  • 1
    No, I am not familiar with the serialization capabilities of the STRtree. I believe it is completely dependent on the serialization of the _tree_handle returned by shapely.geos.GEOSSTRtree_create(max(2, len(geoms))) – Phil Sep 15 '17 at 23:38
  • Note that a more up to date Shapely manual is located here: shapely.readthedocs.io/en/stable – K.-Michael Aye Jan 10 '18 at 20:35

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.