In testing an object detection algorithm in large images, we check our detected bounding boxes against the coordinates given for the ground truth rectangles.

According to the Pascal VOC challenges, there's this:

A predicted bounding box is considered correct if it overlaps more than 50% with a ground-truth bounding box, otherwise the bounding box is considered a false positive detection. Multiple detections are penalized. If a system predicts several bounding boxes that overlap with a single ground-truth bounding box, only one prediction is considered correct, the others are considered false positives.

This means that we need to calculate the percentage of overlap. Does this mean that the ground truth box is 50% covered by the detected boundary box? Or that 50% of the bounding box is absorbed by the ground truth box?

I've searched but I haven't found a standard algorithm for this - which is surprising because I would have thought that this is something pretty common in computer vision. (I'm new to it). Have I missed it? Does anyone know what the standard algorithm is for this type of problem?


For axis-aligned bounding boxes it is relatively simple. "Axis-aligned" means that the bounding box isn't rotated; or in other words that the boxes lines are parallel to the axes. Here's how to calculate the IoU of two axis-aligned bounding boxes.

def get_iou(bb1, bb2):
    Calculate the Intersection over Union (IoU) of two bounding boxes.

    bb1 : dict
        Keys: {'x1', 'x2', 'y1', 'y2'}
        The (x1, y1) position is at the top left corner,
        the (x2, y2) position is at the bottom right corner
    bb2 : dict
        Keys: {'x1', 'x2', 'y1', 'y2'}
        The (x, y) position is at the top left corner,
        the (x2, y2) position is at the bottom right corner

        in [0, 1]
    assert bb1['x1'] < bb1['x2']
    assert bb1['y1'] < bb1['y2']
    assert bb2['x1'] < bb2['x2']
    assert bb2['y1'] < bb2['y2']

    # determine the coordinates of the intersection rectangle
    x_left = max(bb1['x1'], bb2['x1'])
    y_top = max(bb1['y1'], bb2['y1'])
    x_right = min(bb1['x2'], bb2['x2'])
    y_bottom = min(bb1['y2'], bb2['y2'])

    if x_right < x_left or y_bottom < y_top:
        return 0.0

    # The intersection of two axis-aligned bounding boxes is always an
    # axis-aligned bounding box
    intersection_area = (x_right - x_left) * (y_bottom - y_top)

    # compute the area of both AABBs
    bb1_area = (bb1['x2'] - bb1['x1']) * (bb1['y2'] - bb1['y1'])
    bb2_area = (bb2['x2'] - bb2['x1']) * (bb2['y2'] - bb2['y1'])

    # compute the intersection over union by taking the intersection
    # area and dividing it by the sum of prediction + ground-truth
    # areas - the interesection area
    iou = intersection_area / float(bb1_area + bb2_area - intersection_area)
    assert iou >= 0.0
    assert iou <= 1.0
    return iou


enter image description here enter image description here

Images are from this answer

  • There is a bug in this code - y_top = max(bb1['y1'], bb2['y1']) should use min. Similarily y_bottom should use max. – James Meakin Mar 14 '18 at 9:56
  • 2
    @JamesMeakin: The code is correct. y=0 is at the top, and increases downwards. – Cris Luengo Jun 26 '18 at 15:17
  • What if the bounding box is not a rectangle? – markroxor Oct 1 '18 at 11:23
  • 2
    Then copy-paste will not work. I only had axis aligned bounding boxes so far in detection. For semantic segmentation there are arbitrary complex shapes. But the concept is the same. – Martin Thoma Oct 1 '18 at 12:00
  • @Chaine I'm not sure what I should write. Don't the docstrings answer your question? – Martin Thoma Oct 2 '18 at 10:56

A Simple way

iou (Image is not drawn to scale)

from shapely.geometry import Polygon

def calculate_iou(box_1, box_2):
    poly_1 = Polygon(box_1)
    poly_2 = Polygon(box_2)
    iou = poly_1.intersection(poly_2).area / poly_1.union(poly_2).area
    return iou

box_1 = [[511, 41], [577, 41], [577, 76], [511, 76]]
box_2 = [[544, 59], [610, 59], [610, 94], [544, 94]]

print(calculate_iou(box_1, box_2))

The result will be 0.138211... which means 13.82%.

  • Nice for using a library which has the functions already. But I am almost 100% sure this code is wrong: iou = poly_1.intersection(poly_2).area / poly_1.union(poly_2).area. You're calculating the area of the intersection of the two boxes. And dividing by the area of the union of the two boxes. Well, go look at the "Jaccard index" (IoU) formula. The correct Jaccard Index formula is: iou = intersection_area / (union_area - intersection_area). – Mitch McMabers Sep 10 at 12:13
  • Actually, turns out that the "union" function in Shapely already ignores the intersection. So your code is correct. Proof: poly_1.area and poly_2.area are both 2310. poly_1.union(poly_2).area is 4059. poly_1.intersection(poly_2).area is 561. And to prove everything: 4059+561 == 2310+2310. Both sum to 4620. So yes, your code is correct and follows the Jaccard formula, because Shapely calculates its union minus intersection. Nice. – Mitch McMabers Sep 10 at 12:39

For the intersection distance, shouldn't we add a +1 so as to have

intersection_area = (x_right - x_left + 1) * (y_bottom - y_top + 1)   

(same for the AABB)
Like on this pyimage search post

I agree (x_right - x_left) x (y_bottom - y_top) works in mathematics with point coordinates but since we deal with pixels it is I think different.

Consider a 1D example :
- 2 points : x1 = 1 and x2 = 3, the distance is indeed x2-x1 = 2
- 2 pixels of index : i1 = 1 and i2 = 3, the segment from pixel i1 to i2 contains 3 pixels ie l = i2 - i1 + 1

  • You are right... A 1920x1080 screen is indexed from 0 (first pixel) to 1919 (last pixel horizontally) and from 0 (first pixel) to 1079 (last pixel vertically). So if we have a rectangle in "pixel coordinate space", to calculate its area we must add 1 in each direction. Otherwise imagine that our 1920x1080 screen has a fullscreen rectangle with left=0,top=0,right=1919,bottom=1079. Well, we know that 1920x1080 pixels is 2073600 pixels. But with the wrong area = (x_right - x_left) * (y_bottom - y_top) math, we get: (1919 - 0) * (1079 - 0) = 1919 * 1079 = 2070601 pixels! – Mitch McMabers Sep 10 at 12:55
  • I've done a bunch of tests to verify, and have now submitted an edit for the accepted answer based on your correct observation. Thanks! I wonder how many codebases have copy-pasted the original, bugged math after all these years. ;-) – Mitch McMabers Sep 10 at 13:09

I found that the conceptual answer is here: http://pascallin.ecs.soton.ac.uk/challenges/VOC/voc2012/htmldoc/devkit_doc.html#SECTION00054000000000000000

from this thread: Compare two bounding boxes with each other Matlab

I should be able to code this in python!

  • Are you looking for polygon intersection code? Because that I have available. – Stefan van der Walt Aug 22 '14 at 18:31
  • Hey thanks, yes! My polygons will all be just boxes but I guess that's not an issue, right? – user961627 Oct 11 '14 at 18:19
  • 1
    Using matplotlib, here's how to compute polygon clipping: github.com/scikit-image/scikit-image/pull/1177/… – Stefan van der Walt Oct 11 '14 at 21:45
  • Thanks - but I'm not that familiar with github so I'm not sure what to do with the link you sent me. It looks like changes over a _geometry.py and draw.py files. But which of these files do I actually need to import? And what would be a one or two-liner code be to assign two rectangles to this polygon type and get the value of how much they intersect? – user961627 Oct 14 '14 at 7:11

In the snippet below, I construct a polygon along the edges of the first box. I then use Matplotlib to clip the polygon to the second box. The resulting polygon contains four vertices, but we are only interested in the top left and bottom right corners, so I take the max and the min of the coordinates to get a bounding box, which is returned to the user.

import numpy as np
from matplotlib import path, transforms

def clip_boxes(box0, box1):
    path_coords = np.array([[box0[0, 0], box0[0, 1]],
                            [box0[1, 0], box0[0, 1]],
                            [box0[1, 0], box0[1, 1]],
                            [box0[0, 0], box0[1, 1]]])

    poly = path.Path(np.vstack((path_coords[:, 0],
                                path_coords[:, 1])).T, closed=True)
    clip_rect = transforms.Bbox(box1)

    poly_clipped = poly.clip_to_bbox(clip_rect).to_polygons()[0]

    return np.array([np.min(poly_clipped, axis=0),
                     np.max(poly_clipped, axis=0)])

box0 = np.array([[0, 0], [1, 1]])
box1 = np.array([[0, 0], [0.5, 0.5]])

print clip_boxes(box0, box1)
  • In terms of coordinates, the returned value represents: [[ x1 y1 ] [ x2 y2 ]], am I right? – user961627 Oct 16 '14 at 6:41
  • And the input boxes should conform to the same coordinates representation as well, right? – user961627 Oct 16 '14 at 6:55
  • 1
    Yes, quite right. – Stefan van der Walt Oct 16 '14 at 10:24
  • Thanks - I've been using it fine for a while! But now it's running into an error sometimes, I'm not sure why: stackoverflow.com/questions/26712637/… – user961627 Nov 3 '14 at 10:52

how about this approach? Could be extended to any number of unioned shapes

surface = np.zeros([1024,1024])
surface[1:1+10, 1:1+10] += 1
surface[100:100+500, 100:100+100] += 1
unionArea = (surface==2).sum()
  • Making a fixed-size matrix like that and filling it with numbers at the offset of each shape seems a bit insane. Try using the Shapely library for Python. It has helper functions for calculating intersections and unions of various shapes. I haven't tried doing arbitrary (non-box) shapes with it, but it is probably possible. – Mitch McMabers Sep 10 at 12:16
  • What I mean by "insane" is: Slow and memory-bloated. The Shapely library handles complex intersections/area calculations using much smarter math, and shortcuts when objects are nowhere near each other at all, etc. And yes, I just verified that Shapely perfectly handles complex shapes, polygons, rotated shapes, etc. – Mitch McMabers Sep 10 at 13:10

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