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I have a few monochrome images (black and white not greyscale) with a few weirdly shaped objects. I'm trying to extract each object using python27, PIL, scipy & numpy and the following method:

  1. Fit a bounding box around each joined-up object
  2. "Extract" each object as an array - for each object / bounding box

I've had a look at and and these do work, but I'm particularly keen to have the bounding box be rectangular to make sure that any "slightly disconnected" bits get included in the bounding box. Ideally to deal with the disconnected bits (e.g. bottom left blobs) I'd have some kind of threshold control. Any ideas on what toolbox would best suit this?

unbounded image example of image bounds

share|improve this question
Have a look at scipy.ndimage. It has everything you need. (particularly label and find_objects, combined with fill_holes and a bit of blurring and thresholding for your "fuzzy" tolerance) I'm running a bit short on time, so hopefully someone else will post a full example :) – Joe Kington Mar 1 '12 at 22:47
up vote 12 down vote accepted

This uses Joe Kington's find_paws function.

import numpy as np
import scipy.ndimage as ndimage
import scipy.spatial as spatial
import scipy.misc as misc
import matplotlib.pyplot as plt
import matplotlib.patches as patches

class BBox(object):
    def __init__(self, x1, y1, x2, y2):
        (x1, y1) is the upper left corner,
        (x2, y2) is the lower right corner,
        with (0, 0) being in the upper left corner.
        if x1 > x2: x1, x2 = x2, x1
        if y1 > y2: y1, y2 = y2, y1
        self.x1 = x1
        self.y1 = y1
        self.x2 = x2
        self.y2 = y2
    def taxicab_diagonal(self):
        Return the taxicab distance from (x1,y1) to (x2,y2)
        return self.x2 - self.x1 + self.y2 - self.y1
    def overlaps(self, other):
        Return True iff self and other overlap.
        return not ((self.x1 > other.x2)
                    or (self.x2 < other.x1)
                    or (self.y1 > other.y2)
                    or (self.y2 < other.y1))
    def __eq__(self, other):
        return (self.x1 == other.x1
                and self.y1 == other.y1
                and self.x2 == other.x2
                and self.y2 == other.y2)

def find_paws(data, smooth_radius = 5, threshold = 0.0001):
    """Detects and isolates contiguous regions in the input array"""
    # Blur the input data a bit so the paws have a continous footprint 
    data = ndimage.uniform_filter(data, smooth_radius)
    # Threshold the blurred data (this needs to be a bit > 0 due to the blur)
    thresh = data > threshold
    # Fill any interior holes in the paws to get cleaner regions...
    filled = ndimage.morphology.binary_fill_holes(thresh)
    # Label each contiguous paw
    coded_paws, num_paws = ndimage.label(filled)
    # Isolate the extent of each paw
    # find_objects returns a list of 2-tuples: (slice(...), slice(...))
    # which represents a rectangular box around the object
    data_slices = ndimage.find_objects(coded_paws)
    return data_slices

def slice_to_bbox(slices):
    for s in slices:
        dy, dx = s[:2]
        yield BBox(dx.start, dy.start, dx.stop+1, dy.stop+1)

def remove_overlaps(bboxes):
    Return a set of BBoxes which contain the given BBoxes.
    When two BBoxes overlap, replace both with the minimal BBox that contains both.
    # list upper left and lower right corners of the Bboxes
    corners = []

    # list upper left corners of the Bboxes
    ulcorners = []

    # dict mapping corners to Bboxes.
    bbox_map = {}

    for bbox in bboxes:
        ul = (bbox.x1, bbox.y1)
        lr = (bbox.x2, bbox.y2)
        bbox_map[ul] = bbox
        bbox_map[lr] = bbox

    # Use a KDTree so we can find corners that are nearby efficiently.
    tree = spatial.KDTree(corners)
    new_corners = []
    for corner in ulcorners:
        bbox = bbox_map[corner]
        # Find all points which are within a taxicab distance of corner
        indices = tree.query_ball_point(
            corner, bbox_map[corner].taxicab_diagonal(), p = 1)
        for near_corner in[indices]:
            near_bbox = bbox_map[tuple(near_corner)]
            if bbox != near_bbox and bbox.overlaps(near_bbox):
                # Expand both bboxes.
                # Since we mutate the bbox, all references to this bbox in
                # bbox_map are updated simultaneously.
                bbox.x1 = near_bbox.x1 = min(bbox.x1, near_bbox.x1)
                bbox.y1 = near_bbox.y1 = min(bbox.y1, near_bbox.y1) 
                bbox.x2 = near_bbox.x2 = max(bbox.x2, near_bbox.x2)
                bbox.y2 = near_bbox.y2 = max(bbox.y2, near_bbox.y2) 
    return set(bbox_map.values())

if __name__ == '__main__':
    fig = plt.figure()
    ax = fig.add_subplot(111)

    data = misc.imread('image.png')
    im = ax.imshow(data)    
    data_slices = find_paws(255-data, smooth_radius = 20, threshold = 22)

    bboxes = remove_overlaps(slice_to_bbox(data_slices))
    for bbox in bboxes:
        xwidth = bbox.x2 - bbox.x1
        ywidth = bbox.y2 - bbox.y1
        p = patches.Rectangle((bbox.x1, bbox.y1), xwidth, ywidth,
                              fc = 'none', ec = 'red')

yields enter image description here

share|improve this answer
Hi there unutbu, thanks for this answer it's awesome! That paws tutorial was a good find, I'd not seen it before. The overlapping slices works for some images (e.g. the example one), but not others. Try as I might, I cannot figure out the reason for this. Any ideas? – user714852 Mar 3 '12 at 0:02
As this is really a separate question to the original one asked I've opened it at:… – user714852 Mar 3 '12 at 18:48
The code now uses a KDTree to find overlapping rectangles. Please test it. I still have many misgivings about my ad-hoc algorithm. The problem of finding overlapping rectangles seems like a "classic problem" and should have a classic answer. What I dream up in a day is unlikely to be anywhere near as good as what many smart people have probably devised over many man-years. – unutbu Mar 4 '12 at 3:07
This answer by J.F. Sebastian suggests a KDTree is overkill until the number of points is significantly greater than 10**6. So doing a brute-force check of all pairs of rectangles would probably do better here. – unutbu Mar 5 '12 at 19:58
On the other hand, in the other question, the nearest neighbor query is only performed once. Here we want to perform ~n such queries. This might make the cost of building the KDTree worth it. The only way to tell which is best is to code up the brute-force algorithm and benchmark both. – unutbu Mar 5 '12 at 20:05

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