Below is my code for scatter plotting the data in my text file. The file I am opening contains two columns. The left column is x coordinates and the right column is y coordinates. the code creates a scatter plot of x vs. y. I need a code to overplot a line of best fit to the data in the scatter plot, and none of the built in pylab function have worked for me.

from matplotlib import *
from pylab import *

with open('file.txt') as f:
   data = [line.split() for line in f.readlines()]
   out = [(float(x), float(y)) for x, y in data]
for i in out:
   title('My Title')
  • possible duplicate of fitting a curved best fit line to a data set in python
    – dg99
    Commented Mar 7, 2014 at 1:30
  • 5
    I don't need a curved best fit line, I need a straight best fit line Commented Mar 7, 2014 at 1:32
  • 3
    dg99, I've looked at that link prior to creating this question and I tried techniques from the link with no success. Commented Mar 7, 2014 at 1:39
  • Can you show us the code that you tried with the polyfit function and describe how it didn't work? Remember to set the deg parameter to 1 in order to get a linear fit. (See docs here.)
    – dg99
    Commented Mar 7, 2014 at 16:52

6 Answers 6


A one-line version of this excellent answer to plot the line of best fit is:

plt.plot(np.unique(x), np.poly1d(np.polyfit(x, y, 1))(np.unique(x)))

Using np.unique(x) instead of x handles the case where x isn't sorted or has duplicate values.

  • I don't understand the (x) at the end. I checked the scipy documentation and don't see an explanation there. How did you know to use that syntax with poly1d?
    – Jarad
    Commented May 22, 2016 at 4:33
  • 4
    @Jarad poly1d returns a function for the line of best fit, which you then evaluate at the points x.
    – 1''
    Commented May 22, 2016 at 4:40
  • 3
    @FortuneFaded: Yes, replace the second np.unique(x) with a 1D array of the x points you'd like to plot the line at.
    – 1''
    Commented Jan 4, 2017 at 2:11
  • 5
    ^ Whoops, you have to replace both of the np.unique(x), not just the second one like I said above.
    – 1''
    Commented Mar 25, 2017 at 5:08
  • 1
    @DialFrost in this case, it's basically equivalent to converting the slope and intercept returned by polyfit (np.array([m, b])) into a function lambda x: m * x + b which you can then evaluate at the points np.unique(x).
    – 1''
    Commented Aug 1, 2022 at 4:16

Assuming line of best fit for a set of points is:

y = a + b * x
b = ( sum(xi * yi) - n * xbar * ybar ) / sum((xi - xbar)^2)
a = ybar - b * xbar

Code and plot

# sample points 
X = [0, 5, 10, 15, 20]
Y = [0, 7, 10, 13, 20]

# solve for a and b
def best_fit(X, Y):

    xbar = sum(X)/len(X)
    ybar = sum(Y)/len(Y)
    n = len(X) # or len(Y)

    numer = sum([xi*yi for xi,yi in zip(X, Y)]) - n * xbar * ybar
    denum = sum([xi**2 for xi in X]) - n * xbar**2

    b = numer / denum
    a = ybar - b * xbar

    print('best fit line:\ny = {:.2f} + {:.2f}x'.format(a, b))

    return a, b

# solution
a, b = best_fit(X, Y)
#best fit line:
#y = 0.80 + 0.92x

# plot points and fit line
import matplotlib.pyplot as plt
plt.scatter(X, Y)
yfit = [a + b * xi for xi in X]
plt.plot(X, yfit)

enter image description here


notebook version

  • 6
    Exactly what I was looking for. Useful that the matplot lib isn't mixed in with the actual LOB algorithm. Thank you Aziz. Commented Oct 3, 2016 at 10:32
  • I had to convert numer and denum to floats. Otherwise I get the wrong result.
    – psyklopz
    Commented Aug 10, 2018 at 1:52
  • numer = float(sum([xi*yi for xi,yi in zip(X, Y)]) - n * xbar * ybar) denum = float(sum([xi2 for xi in X]) - n * xbar2)
    – psyklopz
    Commented Aug 10, 2018 at 1:52
  • @AzizAlto Great work!!. Just want to know how to find the end (x,y) coordinates of this best fit line ? Commented Sep 5, 2018 at 14:38
  • @ShubhamS.Naik thanks, do you mean the last X and yfit points? if so they would, X[-1] and yfit[-1]
    – Aziz Alto
    Commented Sep 5, 2018 at 15:57

You can use numpy's polyfit. I use the following (you can safely remove the bit about coefficient of determination and error bounds, I just think it looks nice):


import numpy as np
import matplotlib.pyplot as plt
import csv

with open("example.csv", "r") as f:
    data = [row for row in csv.reader(f)]
    xd = [float(row[0]) for row in data]
    yd = [float(row[1]) for row in data]

# sort the data
reorder = sorted(range(len(xd)), key = lambda ii: xd[ii])
xd = [xd[ii] for ii in reorder]
yd = [yd[ii] for ii in reorder]

# make the scatter plot
plt.scatter(xd, yd, s=30, alpha=0.15, marker='o')

# determine best fit line
par = np.polyfit(xd, yd, 1, full=True)

xl = [min(xd), max(xd)]
yl = [slope*xx + intercept  for xx in xl]

# coefficient of determination, plot text
variance = np.var(yd)
residuals = np.var([(slope*xx + intercept - yy)  for xx,yy in zip(xd,yd)])
Rsqr = np.round(1-residuals/variance, decimals=2)
plt.text(.9*max(xd)+.1*min(xd),.9*max(yd)+.1*min(yd),'$R^2 = %0.2f$'% Rsqr, fontsize=30)

plt.xlabel("X Description")
plt.ylabel("Y Description")

# error bounds
yerr = [abs(slope*xx + intercept - yy)  for xx,yy in zip(xd,yd)]
par = np.polyfit(xd, yerr, 2, full=True)

yerrUpper = [(xx*slope+intercept)+(par[0][0]*xx**2 + par[0][1]*xx + par[0][2]) for xx,yy in zip(xd,yd)]
yerrLower = [(xx*slope+intercept)-(par[0][0]*xx**2 + par[0][1]*xx + par[0][2]) for xx,yy in zip(xd,yd)]

plt.plot(xl, yl, '-r')
plt.plot(xd, yerrLower, '--r')
plt.plot(xd, yerrUpper, '--r')

Have implemented @Micah 's solution to generate a trendline with a few changes and thought I'd share:

  • Coded as a function
  • Option for a polynomial trendline (input order=2)
  • Function can also just return the coefficient of determination (R^2, input Rval=True)
  • More Numpy array optimisations


def trendline(xd, yd, order=1, c='r', alpha=1, Rval=False):
    """Make a line of best fit"""

    #Calculate trendline
    coeffs = np.polyfit(xd, yd, order)

    intercept = coeffs[-1]
    slope = coeffs[-2]
    power = coeffs[0] if order == 2 else 0

    minxd = np.min(xd)
    maxxd = np.max(xd)

    xl = np.array([minxd, maxxd])
    yl = power * xl ** 2 + slope * xl + intercept

    #Plot trendline
    plt.plot(xl, yl, c, alpha=alpha)

    #Calculate R Squared
    p = np.poly1d(coeffs)

    ybar = np.sum(yd) / len(yd)
    ssreg = np.sum((p(xd) - ybar) ** 2)
    sstot = np.sum((yd - ybar) ** 2)
    Rsqr = ssreg / sstot

    if not Rval:
        #Plot R^2 value
        plt.text(0.8 * maxxd + 0.2 * minxd, 0.8 * np.max(yd) + 0.2 * np.min(yd),
                 '$R^2 = %0.2f$' % Rsqr)
        #Return the R^2 value:
        return Rsqr
import matplotlib.pyplot as plt    
from sklearn.linear_model import LinearRegression

X, Y = x.reshape(-1,1), y.reshape(-1,1)
plt.plot( X, LinearRegression().fit(X, Y).predict(X) )

Numpy 1.4 introduced new API. You can use this one-liner, where n determines how smooth you want the line to be and a is the degree of the polynomial.

plt.plot(*np.polynomial.Polynomial.fit(x, y, a).linspace(n), 'r-')

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.