I have a set of points (black dots in geographic coordinate value) derived from the convex hull (blue) of a polygon (red). see Figure:enter image description here


I need to calculate the the major and minor axis length following these steps (form this post write in R-project and in Java) or following the this example procedure

enter image description here

  1. Compute the convex hull of the cloud.
  2. For each edge of the convex hull: 2a. compute the edge orientation, 2b. rotate the convex hull using this orientation in order to compute easily the bounding rectangle area with min/max of x/y of the rotated convex hull, 2c. Store the orientation corresponding to the minimum area found,
  3. Return the rectangle corresponding to the minimum area found.

After that we know the The angle Theta (represented the orientation of the bounding rectangle relative to the y-axis of the image). The minimum and maximum of a and b over all boundary points are found:

  • a(xi,yi) = xi*cos Theta + yi sin Theta
  • b(xi,yi) = xi*sin Theta + yi cos Theta

The values (a_max - a_min) and (b_max - b_min) defined the length and width, respectively, of the bounding rectangle for a direction Theta.

enter image description here

  • 3
    You've already found the algorithm - What's your question?
    – Eric
    Nov 24, 2012 at 16:24
  • @Eric, thanks for replay. I am looking if in Python this algorithm is already implemented (ex: in shapely or other module) Nov 24, 2012 at 16:25
  • 3
    So your question is "Does a module exist which already does this?"
    – Eric
    Nov 24, 2012 at 16:26
  • 1
    Cross-posted at gis.stackexchange.com/questions/22895/….
    – whuber
    Feb 4, 2013 at 14:59
  • 1
    I have created and tested a package for this problem. The Post. The Repo May 25, 2017 at 3:27

6 Answers 6


I just implemented this myself, so I figured I'd drop my version here for others to view:

import numpy as np
from scipy.spatial import ConvexHull

def minimum_bounding_rectangle(points):
    Find the smallest bounding rectangle for a set of points.
    Returns a set of points representing the corners of the bounding box.

    :param points: an nx2 matrix of coordinates
    :rval: an nx2 matrix of coordinates
    from scipy.ndimage.interpolation import rotate
    pi2 = np.pi/2.

    # get the convex hull for the points
    hull_points = points[ConvexHull(points).vertices]

    # calculate edge angles
    edges = np.zeros((len(hull_points)-1, 2))
    edges = hull_points[1:] - hull_points[:-1]

    angles = np.zeros((len(edges)))
    angles = np.arctan2(edges[:, 1], edges[:, 0])

    angles = np.abs(np.mod(angles, pi2))
    angles = np.unique(angles)

    # find rotation matrices
    # XXX both work
    rotations = np.vstack([
#     rotations = np.vstack([
#         np.cos(angles),
#         -np.sin(angles),
#         np.sin(angles),
#         np.cos(angles)]).T
    rotations = rotations.reshape((-1, 2, 2))

    # apply rotations to the hull
    rot_points = np.dot(rotations, hull_points.T)

    # find the bounding points
    min_x = np.nanmin(rot_points[:, 0], axis=1)
    max_x = np.nanmax(rot_points[:, 0], axis=1)
    min_y = np.nanmin(rot_points[:, 1], axis=1)
    max_y = np.nanmax(rot_points[:, 1], axis=1)

    # find the box with the best area
    areas = (max_x - min_x) * (max_y - min_y)
    best_idx = np.argmin(areas)

    # return the best box
    x1 = max_x[best_idx]
    x2 = min_x[best_idx]
    y1 = max_y[best_idx]
    y2 = min_y[best_idx]
    r = rotations[best_idx]

    rval = np.zeros((4, 2))
    rval[0] = np.dot([x1, y2], r)
    rval[1] = np.dot([x2, y2], r)
    rval[2] = np.dot([x2, y1], r)
    rval[3] = np.dot([x1, y1], r)

    return rval

Here are four different examples of it in action. For each example, I generated 4 random points and found the bounding box.


(edit by @heltonbiker) A simple code for plotting:

import matplotlib.pyplot as plt
for n in range(10):
    points = np.random.rand(4,2)
    plt.scatter(points[:,0], points[:,1])
    bbox = minimum_bounding_rectangle(points)
    plt.fill(bbox[:,0], bbox[:,1], alpha=0.2)

(end edit)

It's relatively quick too for these samples on 4 points:

>>> %timeit minimum_bounding_rectangle(a)
1000 loops, best of 3: 245 µs per loop

Link to the same answer over on gis.stackexchange for my own reference.

  • Awesome solution, does its job spot on! For me, some minor source code tweaks was necessary to get it running - hull => hull_points and rval = np.zeros((4,2)). thank you so much for sharing it Mar 23, 2016 at 14:42
  • @SerjZaharchenko Sorry about that! With my last edit I was using two different variable names in the code. I just updated it with the fixes you mentioned and updated the sample images. Thanks for the heads up! Mar 23, 2016 at 19:55

There is a module that does this already on github. https://github.com/BebeSparkelSparkel/MinimumBoundingBox

All you need to do is insert your point cloud into it.

from MinimumBoundingBox import minimum_bounding_box
points = ( (1,2), (5,4), (-1,-3) )
bounding_box = minimum_bounding_box(points)  # returns namedtuple

You can get the major and minor axis lengths by:

minor = min(bounding_box.length_parallel, bounding_box.length_orthogonal)
major = max(bounding_box.length_parallel, bounding_box.length_orthogonal)

It also returns area, rectangle center, rectangle angle, and corner points.

  • I think this answer deserves more upvotes. It worked well for me out of the box.
    – biomiker
    Mar 27, 2017 at 10:26
  • Thanks I thought that too! Apr 3, 2017 at 16:41
  • Pretty neat. Your .py file saved me a ton of time. Worked right out of the box. Pretty quick with 50,000 coordinate points.
    – EA304GT
    Sep 20, 2021 at 19:14
  • Please note that. The order of corner_points needs to be checked to have clockwise or counterclockwise corner points.
    – Alex Xu
    Sep 11, 2023 at 1:36

Given a clockwise-ordered list of n points in the convex hull of a set of points, it is an O(n) operation to find the minimum-area enclosing rectangle. (For convex-hull finding, in O(n log n) time, see activestate.com recipe 66527 or see the quite compact Graham scan code at tixxit.net.)

The following python program uses techniques similar to those of the usual O(n) algorithm for computing maximum diameter of a convex polygon. That is, it maintains three indexes (iL, iP, iR) to the leftmost, opposite, and rightmost points relative to a given baseline. Each index advances through at most n points. Sample output from the program is shown next (with an added header):

 i iL iP iR    Area
 0  6  8  0   203.000
 1  6  8  0   211.875
 2  6  8  0   205.800
 3  6 10  0   206.250
 4  7 12  0   190.362
 5  8  0  1   203.000
 6 10  0  4   201.385
 7  0  1  6   203.000
 8  0  3  6   205.827
 9  0  3  6   205.640
10  0  4  7   187.451
11  0  4  7   189.750
12  1  6  8   203.000

For example, the i=10 entry indicates that relative to the baseline from point 10 to 11, point 0 is leftmost, point 4 is opposite, and point 7 is rightmost, yielding an area of 187.451 units.

Note that the code uses mostfar() to advance each index. The mx, my parameters to mostfar() tell it what extreme to test for; as an example, with mx,my = -1,0, mostfar() will try to maximize -rx (where rx is the rotated x of a point), thus finding the leftmost point. Note that an epsilon allowance probably should be used when if mx*rx + my*ry >= best is done in inexact arithmetic: when a hull has numerous points, rounding error may be a problem and cause the method to incorrectly not advance an index.

Code is shown below. The hull data is taken from the question above, with irrelevant large offsets and identical decimal places elided.

import math

hull = [(23.45, 57.39), (23.45, 60.39), (24.45, 63.39),
        (26.95, 68.39), (28.45, 69.89), (34.95, 71.89),
        (36.45, 71.89), (37.45, 70.39), (37.45, 64.89),
        (36.45, 63.39), (34.95, 61.39), (26.95, 57.89),
        (25.45, 57.39), (23.45, 57.39)]

def mostfar(j, n, s, c, mx, my): # advance j to extreme point
    xn, yn = hull[j][0], hull[j][1]
    rx, ry = xn*c - yn*s, xn*s + yn*c
    best = mx*rx + my*ry
    while True:
        x, y = rx, ry
        xn, yn = hull[(j+1)%n][0], hull[(j+1)%n][1]
        rx, ry = xn*c - yn*s, xn*s + yn*c
        if mx*rx + my*ry >= best:
            j = (j+1)%n
            best = mx*rx + my*ry
            return (x, y, j)

n = len(hull)
iL = iR = iP = 1                # indexes left, right, opposite
pi = 4*math.atan(1)
for i in range(n-1):
    dx = hull[i+1][0] - hull[i][0]
    dy = hull[i+1][1] - hull[i][1]
    theta = pi-math.atan2(dy, dx)
    s, c = math.sin(theta), math.cos(theta)
    yC = hull[i][0]*s + hull[i][1]*c

    xP, yP, iP = mostfar(iP, n, s, c, 0, 1)
    if i==0: iR = iP
    xR, yR, iR = mostfar(iR, n, s, c,  1, 0)
    xL, yL, iL = mostfar(iL, n, s, c, -1, 0)
    area = (yP-yC)*(xR-xL)

    print '    {:2d} {:2d} {:2d} {:2d} {:9.3f}'.format(i, iL, iP, iR, area)

Note: To get the length and width of the minimal-area enclosing rectangle, modify the above code as shown below. This will produce an output line like

Min rectangle:  187.451   18.037   10.393   10    0    4    7

in which the second and third numbers indicate the length and width of the rectangle, and the four integers give index numbers of points that lie upon sides of it.

# add after pi = ... line:
minRect = (1e33, 0, 0, 0, 0, 0, 0) # area, dx, dy, i, iL, iP, iR

# add after area = ... line:
    if area < minRect[0]:
        minRect = (area, xR-xL, yP-yC, i, iL, iP, iR)

# add after print ... line:
print 'Min rectangle:', minRect
# or instead of that print, add:
print 'Min rectangle: ',
for x in ['{:3d} '.format(x) if isinstance(x, int) else '{:7.3f} '.format(x) for x in minRect]:
    print x,
  • Really Thanks for your effort. you are really great. I wish a moment to study your code. The final output that i wish in order to calculate my metric is the length (L) and width (W) of the rectangle with minimum area. You code can be a milestone for start to extract L and W Nov 24, 2012 at 20:25
  • Dear jwpat7, I am trying to understand your help alsp using this webstie valis.cs.uiuc.edu/~sariel/research/CG/applets/… the method here seems to use the lower points as the start point Nov 25, 2012 at 16:07
  • Dear jwpat7, thanks for your time and sorry if i ask this question. Is it possible to extract Length and width of the minimum rectangle area? soory again i don't wish abuse of you, but for me it's really important to get Length and width Nov 25, 2012 at 16:24
  • Dear jwpat7, first of all thanks, you are really nice person. I am writing your function (and i will post under your name because you are the author) in order to have a single function that return Length,width,Area of a given list of point L, W, A = get_minimum_area_rectangle(hull). I wish to do share this approach because in 5 days i didn't find this function implemented in python Nov 25, 2012 at 17:38
  • 2
    This algorithm will fail if by pure coincidence the base for the minimum area rectangle is the edge between hull[n] and hull[0]. A simple solution would be to replace for i in range(n-1): with for i in range(n): and dx = ... with dx = hull[(i+1)%n, 0] - hull[i, 0] (dy respectively). At least this is the case (and the solution works) for something like hull = np.array([[0,0],[1,2],[4,2.2],[7,2],[8,0]], np.float32) Mar 28, 2017 at 15:53

OpenCV has this. See this:


7.b. Rotated Rectangle



You can get the length and width of the rectangle as well as its angle. You can also compute the corners if you wish to draw it.


I found recipe to compute convex hulls.

If we are talking about "full solutions" (one function to do whole stuff), I found only arcpy which is part of ArcGIS program. It provides MinimumBoundingGeometry_management function which looks like what you are looking for. But it's not open source. Unfortunately, there is lack of python open source GIS libraries.

  • thanks. I know arcpy module, but i prefer don't work with not open source (Python philosophy). By the way, it's strange there isn't a module able to calculate this indices from a set of points Nov 24, 2012 at 18:41

Originally posted in Feb 2013:

The above code example is not robust. I tested it with real data (a convex hull of many points) and it produced a result that was close to correct. However for simple 4 to 6 sided polygons it does not work.

Here is a self-contained solution, written in Python: https://github.com/dbworth/minimum-area-bounding-rectangle/

The convex hull is found using a 2D implementation of the qhull (QuickHull) algorithm. The solution is to calculate the angles of all edges of the polygon, then operate only on those angles that are unique to the first quadrant (90 degrees) of rotation. After finding the minimum-area bounding rectangle, it outputs all the data, including the center point and corner points. A simple test program is provided. The answers were validated using Matlab.

Note that this solution relies on the assumption that the bounding box will share at least one edge with the input polygon. This suited my application, however I heard there is a paper where the author showed there are some rare solutions where this is not true. If this result is important, you should look into it!

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