# Calculate area of polygon given (x,y) coordinates

I have a set of points and would like to know if there is a function (for the sake of convenience and probably speed) that can calculate the area enclosed by a set of points.

for example:

``````x = np.arange(0,1,0.001)
y = np.sqrt(1-x**2)

points = zip(x,y)
``````

given `points` the area should be approximately equal to `(pi-2)/4`. Maybe there is something from scipy, matplotlib, numpy, shapely, etc. to do this? I won't be encountering any negative values for either the x or y coordinates... and they will be polygons without any defined function.

EDIT:

points will most likely not be in any specified order (clockwise or counterclockwise) and may be quite complex as they are a set of utm coordinates from a shapefile under a set of boundaries

Implementation of Shoelace formula could be done in `Numpy`. Assuming these vertices:

``````import numpy as np
x = np.arange(0,1,0.001)
y = np.sqrt(1-x**2)
``````

We can redefine the function in numpy to find the area:

``````def PolyArea(x,y):
return 0.5*np.abs(np.dot(x,np.roll(y,1))-np.dot(y,np.roll(x,1)))
``````

And getting results:

``````print PolyArea(x,y)
# 0.26353377782163534
``````

Avoiding `for` loop makes this function ~50X faster than `PolygonArea`:

``````%timeit PolyArea(x,y)
# 10000 loops, best of 3: 42 µs per loop
%timeit PolygonArea(zip(x,y))
# 100 loops, best of 3: 2.09 ms per loop.
``````

Timing is done in Jupyter notebook.

• Great solution. I'm not sure why, but the "top" answer by @Nikos Athanasiou does not work when some of the coordinates are negative. Also another solution listed here had that issue. Your solution is the only one that worked. Just check with `xxx = np.array([[-100,0],[100,0],[100,150],[-100,150],[-100,0]])` Commented Jun 19, 2015 at 7:48
• @user989762: But I am getting the same answer using both methods! Commented Jun 20, 2015 at 6:04
• rookie mistake: not providing the points in an ordered (clockwise/counter clockwise) manner would yield faulty results. Commented Jul 25, 2018 at 12:55
• Can you explain how you used the dot product instead of the cross product as the shoelace forumla states? Commented Dec 13, 2019 at 19:08
• @pstatix: Indeed the shoelace formula can be written in terms of the exterior product but you can expand the product, and you'll see there are two types of terms: positive terms and negative terms. If you separate them into two terms, you'd see they are the product of x and y then you can write those x's and y's as two vectors with a dot product between them. Look at the `proof for a triangle` section here: en.wikipedia.org/wiki/Shoelace_formula Commented Dec 14, 2019 at 20:57

The most optimized solution that covers all possible cases, would be to use a geometry package, like shapely, scikit-geometry or pygeos. All of them use C++ geometry packages under the hood. The first one is easy to install via pip:

``````pip install shapely
``````

and simple to use:

``````from shapely.geometry import Polygon
pgon = Polygon(zip(x, y)) # Assuming the OP's x,y coordinates

print(pgon.area)
``````

To build it from scratch or understand how the underlying algorithm works, check the shoelace formula:

``````# e.g. corners = [(2.0, 1.0), (4.0, 5.0), (7.0, 8.0)]
def Area(corners):
n = len(corners) # of corners
area = 0.0
for i in range(n):
j = (i + 1) % n
area += corners[i][0] * corners[j][1]
area -= corners[j][0] * corners[i][1]
area = abs(area) / 2.0
return area
``````

Since this works for simple polygons:

• If you have a polygon with holes : Calculate the area of the outer ring and subtrack the areas of the inner rings

• If you have self-intersecting rings : You have to decompose them into simple sectors

• Mine might be very complex polygons. The points are utm coordinates selected from a shapefile under a set of boundaries Commented Jun 28, 2014 at 15:01
• @user2593236: So long as your polygon boundary doesn't cross itself (which is what "simple" means in this context), you should be fine. Commented Jun 28, 2014 at 15:05
• @user2593236 Simple means concave or convex without holes or self intersections. Commented Jun 28, 2014 at 15:05
• I tried with very simple coordinates `[(0.0, 0.0), (1.0, 0.0), (0.0, 1.0), (1.0, 1.0)]` and it gave 0.0 area. Are there any limitations that you know? Also tried to shift it out of the origin, getting the same result. Commented Apr 6, 2017 at 20:53
• @diegopso seems that it works only if the points are in a series of drawing. So it will work for `[(0, 0), (0, 1), (1, 1), (1, 0)]` Commented Mar 13, 2019 at 21:39

By analysis of Mahdi's answer, I concluded that the majority of time was spent doing `np.roll()`. By removing the need of the roll, and still using numpy, I got the execution time down to 4-5µs per loop compared to Mahdi's 41µs (for comparison Mahdi's function took an average of 37µs on my machine).

``````def polygon_area(x,y):
correction = x[-1] * y[0] - y[-1]* x[0]
main_area = np.dot(x[:-1], y[1:]) - np.dot(y[:-1], x[1:])
return 0.5*np.abs(main_area + correction)
``````

By calculating the correctional term, and then slicing the arrays, there is no need to roll or create a new array.

Benchmarks:

``````10000 iterations
PolyArea(x,y): 37.075µs per loop
polygon_area(x,y): 4.665µs per loop
``````

Timing was done using the `time` module and `time.clock()`

• I get a difference between this approach and the one of Mahdi when I define `x` and `y` such as `x_{n+1} = x_1 and x_0 = x_n, as well as y_{n+1} = y_1 and y_0 = y_n` as required to apply the shoelace formula (see en.wikipedia.org/wiki/Shoelace_formula#Definition) The difference is slight because the points are the vertices are so close to each other but exists and may be magnified when working with polygons with longer sides. Commented Sep 27, 2018 at 16:23
• Of course there are floating point errors, as with any implementation. Could you provide a full example of the difference? If you need more precision, you could use arbitrary precision arithmetics.
– maxb
Commented Sep 27, 2018 at 16:45
• My bad, I was confused about the correction term and thought that some difference I could observe could come from there while tracking a bug in my code. Seems to work perfectly after many more tests comparing different implementations for computing the area of polygons. Your solution has the speed advantage as well as being easy to read! Commented Sep 27, 2018 at 17:54
• @Eskapp glad to hear everything is working correctly!
– maxb
Commented Sep 27, 2018 at 19:52
• @pstatix if you look at the Wikipedia article for the Shoelace formula, it can be visualized as a shifted dot product. I didn't come up with the formula myself, but I did realize that the pattern of calculation used directly matched using the dot product (or rather two dot products), with one vector in each product shifted around. For more info I'd just read the article, the only thing I did for this answer was to improve the performance of the algorithm.
– maxb
Commented Dec 14, 2019 at 21:19

maxb's answer gives good performance but can easily lead to loss of precision when coordinate values or the number of points are large. This can be mitigated with a simple coordinate shift:

``````def polygon_area(x,y):
# coordinate shift
x_ = x - x.mean()
y_ = y - y.mean()
# everything else is the same as maxb's code
correction = x_[-1] * y_[0] - y_[-1]* x_[0]
main_area = np.dot(x_[:-1], y_[1:]) - np.dot(y_[:-1], x_[1:])
return 0.5*np.abs(main_area + correction)
``````

For example, a common geographic reference system is UTM, which might have (x,y) coordinates of `(488685.984, 7133035.984)`. The product of those two values is `3485814708748.448`. You can see that this single product is already at the edge of precision (it has the same number of decimal places as the inputs). Adding just a few of these products, let alone thousands, will result in loss of precision.

A simple way to mitigate this is to shift the polygon from large positive coordinates to something closer to (0,0), for example by subtracting the centroid as in the code above. This helps in two ways:

1. It eliminates a factor of `x.mean() * y.mean()` from each product
2. It produces a mix of positive and negative values within each dot product, which will largely cancel.

The coordinate shift does not alter the total area, it just makes the calculation more numerically stable.

• The only solution that offered the correct result! Kudos! See my answer for an slightly modified version that takes a list of tuples. Commented Oct 20, 2020 at 10:46

cv2.contourArea() in OpenCV gives an alternative method.

example:

``````points = np.array([[0,0],[10,0],[10,10],[0,10]])
area = cv2.contourArea(points)
print(area) # 100.0
``````

The argument (points, in the above example) is a numpy array with dtype int, representing the vertices of a polygon: [[x1,y1],[x2,y2], ...]

• You did not mention here that it works for integer arrays Commented Dec 22, 2020 at 16:22
• This actually seems the fastest, at least for the simple polygons I tested Commented May 21, 2021 at 13:04
• you could use `cv2.contourArea(np.around(np.array([[pt] for pt in points])).astype(np.int32))` Commented Jul 28, 2023 at 15:20

There's an error in the code above as it doesn't take absolute values on each iteration. The above code will always return zero. (Mathematically, it's the difference between taking signed area or wedge product and the actual area http://en.wikipedia.org/wiki/Exterior_algebra.) Here's some alternate code.

``````def area(vertices):
n = len(vertices) # of corners
a = 0.0
for i in range(n):
j = (i + 1) % n
a += abs(vertices[i][0] * vertices[j][1]-vertices[j][0] * vertices[i][1])
result = a / 2.0
return result
``````

a bit late here, but have you considered simply using sympy?

a simple code is :

``````from sympy import Polygon
a = Polygon((0, 0), (2, 0), (2, 2), (0, 2)).area
print(a)
``````

It's faster to use `shapely.geometry.Polygon` rather than to calculate yourself.

``````from shapely.geometry import Polygon
import numpy as np
def PolyArea(x,y):
return 0.5*np.abs(np.dot(x,np.roll(y,1))-np.dot(y,np.roll(x,1)))
coords = np.random.rand(6, 2)
x, y = coords[:, 0], coords[:, 1]
``````

With those codes, and do `%timeit`

``````%timeit PolyArea(x,y)
46.4 µs ± 2.24 µs per loop (mean ± std. dev. of 7 runs, 10000 loops each)
%timeit Polygon(coords).area
20.2 µs ± 414 ns per loop (mean ± std. dev. of 7 runs, 100000 loops each)
``````
• numpy is quite standard, but shapely is abit faster Commented Oct 10, 2020 at 2:41

I compared every solutions offered here to Shapely's area method result, they had the right integer part but the decimal numbers differed. Only @Trenton's solution provided the the correct result.

Now improving on @Trenton's answer to process coordinates as a list of tuples, I came up with the following:

``````import numpy as np

def polygon_area(coords):
# get x and y in vectors
x = [point[0] for point in coords]
y = [point[1] for point in coords]
# shift coordinates
x_ = x - np.mean(x)
y_ = y - np.mean(y)
# calculate area
correction = x_[-1] * y_[0] - y_[-1] * x_[0]
main_area = np.dot(x_[:-1], y_[1:]) - np.dot(y_[:-1], x_[1:])
return 0.5 * np.abs(main_area + correction)

#### Example output
coords = [(385495.19520441635, 6466826.196947694), (385496.1951836388, 6466826.196947694), (385496.1951836388, 6466825.196929455), (385495.19520441635, 6466825.196929455), (385495.19520441635, 6466826.196947694)]

Shapely's area method:  0.9999974610685296
@Trenton's area method: 0.9999974610685296
``````

This is much simpler, for regular polygons:

``````import math

def area_polygon(n, s):
return 0.25 * n * s**2 / math.tan(math.pi/n)
``````

since the formula is ¼ n s2 / tan(π/n). Given the number of sides, n, and the length of each side, s

• Interesting. Seems like this would be fast and easy to jit compile with numba. Do you have a reference for this? Commented Jan 21, 2016 at 17:56
• # Given the number of sides, n, and the length of each side, s, the polygon's area is # 1/4 n s2 / tan( pi/n) Interactive Python (Rice University, Coursera) again here: Area of a Polygon (academia.edu/5179705/Exercise_1_How_to_design_programs) I did the function from that... Commented Jan 22, 2016 at 9:12
• This is for a regular polygon which is a special but very limited case of this problem. All sides must be the same length (which would need to be calculated as well). If you explained what `n` and `s` are then maybe it would be more apparent... Commented Jan 22, 2016 at 16:56

Based on

https://www.mathsisfun.com/geometry/area-irregular-polygons.html

``````def _area_(coords):
t=0
for count in range(len(coords)-1):
y = coords[count+1][1] + coords[count][1]
x = coords[count+1][0] - coords[count][0]
z = y * x
t += z
return abs(t/2.0)

a=[(5.09,5.8), (1.68,4.9), (1.48,1.38), (4.76,0.1), (7.0,2.83), (5.09,5.8)]
print _area_(a)
``````

The trick is that the first coordinate should also be last.

• It gave wrong result when I tried more complex area with 15 vertices. Commented Jun 17, 2019 at 8:06
• can you please provide the coordinates? Commented Jun 18, 2019 at 11:21
• Sorry it is my fault. I tested your code a few times and compared the results with CAD software, I tested coords=[(1141.784,893.124), (1521.933,893.124), (1521.933,999.127), (1989.809,999.127), (1989.809,622.633), (2125.054,622.633), (2125.054,326.556), (1372.067,326.556), (1372.067,-60.903), (1872.84,-60.903), (1872.84,52.41), (2015.396,52.41), (2015.396,-455.673), (1090.611,-455.673), (1086.955,436.214), (1141.784,893.124)] Yesterday I got wrong result maybe I missed something, today it works great like PolygonArea function. Commented Jun 18, 2019 at 12:14
• I think I comment it by mistake, maybe I tried another function here yesterday. Commented Jun 18, 2019 at 12:17
• Glad I could help Commented Jun 19, 2019 at 15:25
``````def find_int_coordinates(n: int, coords: list[list[int]]) -> float:
rez = 0
x, y = coords[n - 1]
for coord in coords:
rez += (x + coord[0]) * (y - coord[1])
x, y = coord
return abs(rez / 2)
``````

Shoelace formula comes from computing internal triangles based on consecutive points around the polygon. It could be more informative to base the code on this explanation. The area of polygon is simply length of cross product (determinant) of its two neighboring vectors divided by two, all added up,

https://youtu.be/0KjG8Pg6LGk?t=213

``````import numpy as np, numpy.linalg as lin

def area(pts):
ps = np.array([0.5 * lin.det(np.vstack((pts[i], pts[i+1]))) for i in range(len(pts)-1)])
s = np.sum(ps)
p1,p2 = pts[-1],pts[0] # cycle back, last pt with the first
s += 0.5 * lin.det(np.vstack((p1,p2)))
return np.abs(s)

points = np.array([[0,0],[10,0],[10,10],[0,10]])
area(points) # 100
``````