# Calculating the area under a curve given a set of coordinates, without knowing the function

I have one list of 100 numbers as height for Y axis, and as length for X axis: 1 to 100 with a constant step of 5. I need to calculate the Area that it is included by the curve of the (x,y) points, and the X axis, using rectangles and Scipy. Do I have to find the function of this curve? or not? ... almost all the examples I have read are about a specific equation for the Y axis. In my case there is no equation, just data from a list. The classic solution is to add or the Y points and multiple by the step X distance... using Scipy any idea?

Please, can anyone recommend any book which focusing on numerical (finite elementary) methods, using Scipy and Numpy? ...

The numpy and scipy libraries include the composite trapezoidal (numpy.trapz) and Simpson's (scipy.integrate.simps) rules.

Here's a simple example. In both `trapz` and `simps`, the argument `dx=5` indicates that the spacing of the data along the x axis is 5 units.

``````from __future__ import print_function

import numpy as np
from scipy.integrate import simps
from numpy import trapz

# The y values.  A numpy array is used here,
# but a python list could also be used.
y = np.array([5, 20, 4, 18, 19, 18, 7, 4])

# Compute the area using the composite trapezoidal rule.
area = trapz(y, dx=5)
print("area =", area)

# Compute the area using the composite Simpson's rule.
area = simps(y, dx=5)
print("area =", area)
``````

Output:

``````area = 452.5
area = 460.0
``````
• that's great! ... Both answers help me to understand and solve any questions I had. I would like to ask something relative... Do you recommend to use arrays and not list? is something that help the user ? or the logic and speed of the algorithm? – user1640255 Nov 10 '12 at 17:44
• The first thing `trapz` and `simps` functions do is convert the `y` argument into a numpy array, so it doesn't really matter. You might look at your code that generates the `y` values, and see if that would benefit from the use of additional numpy or scipy functions. If so, `y` would already be an array when you passed it to `simps`. – Warren Weckesser Nov 10 '12 at 20:58
• which one these two methods are more accurate? – Färid Alijani Nov 1 at 6:51

You can use Simpsons rule or the Trapezium rule to calculate the area under a graph given a table of y-values at a regular interval.

Python script that calculates Simpsons rule:

``````def integrate(y_vals, h):
i = 1
total = y_vals + y_vals[-1]
for y in y_vals[1:-1]:
if i % 2 == 0:
total += 2 * y
else:
total += 4 * y
i += 1
``````

`h` is the offset (or gap) between y values, and `y_vals` is an array of well, y values.

Example (In same file as above function):

``````y_values = [13, 45.3, 12, 1, 476, 0]
interval = 1.2
area = integrate(y_values, interval)
print("The area is", area)
``````
• I'm not sure.. it could be really tricky finding the equation of a line, especially if you don't know the type of curve it is (exponential, parabola, etc) – Will Richardson Nov 10 '12 at 8:16
• THANK you ... I really appreciate your help... just y_vals is array ? or my Y data list (H[i]) ? Is better to use arrays, not a list? do recommend to change my list to array? and about h, "h is the x-interval between y values" ? .. little help on this... on the wiki example say: """f=function, a=initial value, b=end value, n=number of intervals of size h, n must be even""" h = float(b - a) / n .. is the same h? so is the distance between each step? – user1640255 Nov 10 '12 at 8:43
• Yes, `h` is the interval between each step. `y_vals` can be anything that can be iterated in a `for` loop. I just always use arrays because they are easy to use. – Will Richardson Nov 10 '12 at 8:48
• ... so the y_vals can be list or array that defined in previous part of the algorithm ? in my case the list is defined as H.... do I have to insert a for loop for the def integrate? – user1640255 Nov 10 '12 at 9:02
• What if the data is not equally spaced out? – CMCDragonkai Oct 11 '15 at 15:17

If you have sklearn isntalled, a simple alternative is to use sklearn.metrics.auc

This computes the area under the curve using the trapezoidal rule given arbitrary x, and y array

``````import numpy as np
from sklearn.metrics import auc

dx = 5
xx = np.arange(1,100,dx)
yy = np.arange(1,100,dx)

print('computed AUC using sklearn.metrics.auc: {}'.format(auc(xx,yy)))
print('computed AUC using np.trapz: {}'.format(np.trapz(yy, dx = dx)))
``````

both output the same area: 4607.5

the advantage of sklearn.metrics.auc is that it can accept arbitrarily-spaced 'x' array, just make sure it is ascending otherwise the results will be incorrect

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