# Linear regression with matplotlib / numpy

I'm trying to generate a linear regression on a scatter plot I have generated, however my data is in list format, and all of the examples I can find of using polyfit require using arange. arange doesn't accept lists though. I have searched high and low about how to convert a list to an array and nothing seems clear. Am I missing something?

Following on, how best can I use my list of integers as inputs to the polyfit?

Here is the polyfit example I am following:

import numpy as np
import matplotlib.pyplot as plt

x = np.arange(data)
y = np.arange(data)

m, b = np.polyfit(x, y, 1)

plt.plot(x, y, 'yo', x, m*x+b, '--k')
plt.show()

arange generates lists (well, numpy arrays); type help(np.arange) for the details. You don't need to call it on existing lists.

>>> x = [1,2,3,4]
>>> y = [3,5,7,9]
>>>
>>> m,b = np.polyfit(x, y, 1)
>>> m
2.0000000000000009
>>> b
0.99999999999999833

I should add that I tend to use poly1d here rather than write out "m*x+b" and the higher-order equivalents, so my version of your code would look something like this:

import numpy as np
import matplotlib.pyplot as plt

x = [1,2,3,4]
y = [3,5,7,10] # 10, not 9, so the fit isn't perfect

coef = np.polyfit(x,y,1)
poly1d_fn = np.poly1d(coef)
# poly1d_fn is now a function which takes in x and returns an estimate for y

plt.plot(x,y, 'yo', x, poly1d_fn(x), '--k') #'--k'=black dashed line, 'yo' = yellow circle marker

plt.xlim(0, 5)
plt.ylim(0, 12)

This code:

from scipy.stats import linregress

linregress(x,y) #x and y are arrays or lists.

gives out a list with the following:

slope : float
slope of the regression line
intercept : float
intercept of the regression line
r-value : float
correlation coefficient
p-value : float
two-sided p-value for a hypothesis test whose null hypothesis is that the slope is zero
stderr : float
Standard error of the estimate

Source

Use statsmodels.api.OLS to get a detailed breakdown of the fit/coefficients/residuals:

import statsmodels.api as sm

df = sm.datasets.get_rdataset('Duncan', 'carData').data
y = df['income']
x = df['education']

results = model.fit()

print(results.params)
# const        10.603498 <- intercept
# education     0.594859 <- slope
# dtype: float64

print(results.summary())
#                             OLS Regression Results
# ==============================================================================
# Dep. Variable:                 income   R-squared:                       0.525
# Model:                            OLS   Adj. R-squared:                  0.514
# Method:                 Least Squares   F-statistic:                     47.51
# Date:                Thu, 28 Apr 2022   Prob (F-statistic):           1.84e-08
# Time:                        00:02:43   Log-Likelihood:                -190.42
# No. Observations:                  45   AIC:                             384.8
# Df Residuals:                      43   BIC:                             388.5
# Df Model:                           1
# Covariance Type:            nonrobust
# ==============================================================================
#                  coef    std err          t      P>|t|      [0.025      0.975]
# ------------------------------------------------------------------------------
# const         10.6035      5.198      2.040      0.048       0.120      21.087
# education      0.5949      0.086      6.893      0.000       0.421       0.769
# ==============================================================================
# Omnibus:                        9.841   Durbin-Watson:                   1.736
# Prob(Omnibus):                  0.007   Jarque-Bera (JB):               10.609
# Skew:                           0.776   Prob(JB):                      0.00497
# Kurtosis:                       4.802   Cond. No.                         123.
# ==============================================================================

## New in matplotlib 3.5.0

To plot the best-fit line, just pass the slope m and intercept b into the new plt.axline:

import matplotlib.pyplot as plt

# extract intercept b and slope m
b, m = results.params

# plot y = m*x + b
plt.axline(xy1=(0, b), slope=m, label=f'\$y = {m:.1f}x {b:+.1f}\$')

Note that the slope m and intercept b can be easily extracted from any of the common regression methods:

• numpy.polyfit

import numpy as np

m, b = np.polyfit(x, y, deg=1)
plt.axline(xy1=(0, b), slope=m, label=f'\$y = {m:.1f}x {b:+.1f}\$')

• scipy.stats.linregress

from scipy import stats

m, b, *_ = stats.linregress(x, y)
plt.axline(xy1=(0, b), slope=m, label=f'\$y = {m:.1f}x {b:+.1f}\$')

• statsmodels.api.OLS

import statsmodels.api as sm

plt.axline(xy1=(0, b), slope=m, label=f'\$y = {m:.1f}x {b:+.1f}\$')

• sklearn.linear_model.LinearRegression

from sklearn.linear_model import LinearRegression

reg = LinearRegression().fit(x[:, None], y)
b = reg.intercept_
m = reg.coef_[0]
plt.axline(xy1=(0, b), slope=m, label=f'\$y = {m:.1f}x {b:+.1f}\$')

import numpy as np
import matplotlib.pyplot as plt
from scipy import stats

x = np.array([1.5,2,2.5,3,3.5,4,4.5,5,5.5,6])
y = np.array([10.35,12.3,13,14.0,16,17,18.2,20,20.7,22.5])
gradient, intercept, r_value, p_value, std_err = stats.linregress(x,y)
mn=np.min(x)
mx=np.max(x)
x1=np.linspace(mn,mx,500)
plt.plot(x,y,'ob')
plt.plot(x1,y1,'-r')
plt.show()

USe this ..

• This doesn't add a new way to tackle the problem - it has already been suggested in this popular answer. May 6, 2018 at 11:53
• do u want to convert generated list into an array? May 6, 2018 at 12:11
• I don't want anything specific, this is not my question. I am just saying that repeating an already established answer is not really, what SO is looking for. Please read the link, I posted. May 6, 2018 at 12:26
• @AleenaRehman I tried to convert a pd DataFrame column to a np.array. There were no commas in between the elements and np.polyfit showed error. Sep 8, 2021 at 6:06

George's answer goes together quite nicely with matplotlib's axline which plots an infinite line.

from scipy.stats import linregress
import matplotlib.pyplot as plt

reg = linregress(x, y)
plt.axline(xy1=(0, reg.intercept), slope=reg.slope, linestyle="--", color="k")
from pylab import *

import numpy as np
x1 = arange(data) #for example this is a list
y1 = arange(data) #for example this is a list
x=np.array(x) #this will convert a list in to an array
y=np.array(y)
m,b = polyfit(x, y, 1)

plot(x, y, 'yo', x, m*x+b, '--k')
show()
• I see, you have written some comments, but you should consider adding a few sentences of explanation, this increases the value of your answer ;-)
– MBT
May 6, 2018 at 12:47
• Please note that while a code snippet can be a useful answer on its own, it's preferable to leave some commentary for future readers about why this solves the problem. Thanks! May 6, 2018 at 16:23
• @blue-phoenox well i thought people are genius here but i guess i will explain next time .. May 6, 2018 at 18:48
• If someone is asking this question it's likely they need help understanding what is in your answer. If you need resources on good answer tips, please see (e.g.) Jon Skeet's blog: codeblog.jonskeet.uk/2009/02/17/… "Code without an explanation is rarely useful, however. At least provide a sentence or two to explain what’s going on." Sep 16, 2022 at 1:14

Another quick and dirty answer is that you can just convert your list to an array using:

import numpy as np
arr = np.asarray(listname)

Linear Regression is a good example for start to Artificial Intelligence

Here is a good example for Machine Learning Algorithm of Multiple Linear Regression using Python:

##### Predicting House Prices Using Multiple Linear Regression - @Y_T_Akademi

#### In this project we are gonna see how machine learning algorithms help us predict house prices. Linear Regression is a model of predicting new future data by using the existing correlation between the old data. Here, machine learning helps us identify this relationship between feature data and output, so we can predict future values.

import pandas as pd

##### we use sklearn library in many machine learning calculations..

from sklearn import linear_model

##### we import out dataset: housepricesdataset.csv

##### The following is our feature set:
##### The following is the output(result) data:
##### we define a linear regression model here:

reg = linear_model.LinearRegression()
reg.fit(df[['area', 'roomcount', 'buildingage']], df['price'])

# Since our model is ready, we can make predictions now:
# lets predict a house with 230 square meters, 4 rooms and 10 years old building..

reg.predict([[230,4,10]])

# Now lets predict a house with 230 square meters, 6 rooms and 0 years old building - its new building..
reg.predict([[230,6,0]])

# Now lets predict a house with 355 square meters, 3 rooms and 20 years old building
reg.predict([[355,3,20]])

# You can make as many prediction as you want..
reg.predict([[230,4,10], [230,6,0], [355,3,20], [275, 5, 17]])

And my dataset is below: