In this article, we will learn how to utilize the functionalities provided by excel and python libraries to calculate IQR,
IQR with Excel and python
In previous article we saw how to calculate the IQR by hand with multiple methods. In this article, we will learn how to utilize the functionalities provided by excel and python libraries to achieve the same.
Calculating Interquartile Range with Excel and python libraries.
In the previous article, how to find IQR with mathematical formulae. Now we will learn to use these mathematical formulas implemented in Excel and various python libraries.
Formula for IQR (Inter Quartile Range)
1. Excel Sheet and Google sheet
In all the quartile functions below, the format for the argument is the same.
QUARTILE(range, Qno)
QUARTILE(A1:A9, 1)
QUARTILE.INC(A1:A9, 1)
QUARTILE.EXC(A1:A9, 1)
Excel provides three functions to calculate quartile, quartile.exc and quartile.inc.
- Quartile()
Quartile provides answers similar to quartile.inc.
- Quartile.inc()
Quartile.inc uses median inclusion method to find quartiles of the provided range of numbers and number of quartile in the function.
- Quartile.exc()
Inversely, Quartile.exc uses median exclusion to find quartiles of the provided range of numbers and numbers of quartile in the function.
In the following example, series column shows a2:a9 cells are filled with dataset.
We are showing a quartile calculated left side table. We are calculating quartiles 1,2 and 3. Which are 25%, 50% and 75% respectively.
We show formulas and arguments for calculating the IQR with each method.
In the following image, we show actual calculations and answers of the series
2. IQR with python numpy quantile function
Following is an example for calculating the quartiles and IQR using python NumPy library.
Python
Tab 3
Python
Python
Tab 3
# import libraries
import numpy as np
import pandas as pd
# create list data series
series=[15,36,39,40,41,42,43,47,49]
# create dataaaframe and insert series as a column
df=pd.DataFrame(data=series,columns=['series'])
print(df)
Output
series
0 15
1 36
2 39
3 40
4 41
5 42
6 43
7 47
8 49Quartiles
Python
Tab 3
Python
Python
Tab 3
# calculate first quartile
q1=np.quantile(df,0.25)
# calculate second quartile
q2=np.quantile(df,0.5)
# calculate three quartile
q3=np.quantile(df,0.75)
print(f'Q1: {q1}\nQ2: {q2}\nQ3: {q3}')
# calculate IQR by substracting Q3 with Q1
print(f'IQR: {q3-q1}')Output
Q1: 39.0
Q2: 41.0
Q3: 43.0
IQR: 4.03. IQR with other methods of Quantile calculation
Python
Tab 3
Python
Python
Tab 3
# Load all the available methods provided by library.
methods=['inverted_cdf','averaged_inverted_cdf','closest_observation','interpolated_inverted_cdf','hazen','weibull','linear','median_unbiased','normal_unbiased']
# traverse through all methods and calculate IQR with each method.
for i in methods:
print(i.upper())
q1=np.quantile(df,0.25,method=i)
q2=np.quantile(df,0.5,method=i)
q3=np.quantile(df,0.75,method=i)
print(f'Q1: {q1}\nQ2: {q2}\nQ3: {q3}')
print(f'IQR: {q3-q1}\n\n')| INVERTED_CDF Q1: 39 Q2: 41 Q3: 43 IQR: 4 | INTERPOLATED_INVERTED_CDF Q1: 36.75 Q2: 40.5 Q3: 42.75 IQR: 6.0 | LINEAR Q1: 39.0 Q2: 41.0 Q3: 43.0 IQR: 4.0 |
| AVERAGED_INVERTED_CDF Q1: 39.0 Q2: 41.0 Q3: 43.0 IQR: 4.0 | HAZEN Q1: 38.25 Q2: 41.0 Q3: 44.0 IQR: 5.75 | MEDIAN_UNBIASED Q1: 38.0 Q2: 41.0 Q3: 44.33333333333333 IQR: 6.333333333333329 |
| CLOSEST_OBSERVATION Q1: 36 Q2: 41 Q3: 43 IQR: 7 | WEIBULL Q1: 37.5 Q2: 41.0 Q3: 45.0 IQR: 7.5 | NORMAL_UNBIASED Q1: 38.0625 Q2: 41.0 Q3: 44.25 IQR: 6.1875 |
4. Python SciPy direct IQR calculation
In the above example, we calculated IQR with NumPy’s quartile function. Let’s calculate IQR directly using SciPy library. This library directly provides ability to calculate IQR of a series. It also provides different interpolation techniques for calculations. Linear, Lower, Higher, Nearest, Midpoint.
Python
Tab 3
Python
Python
Tab 3
interpol = ['linear', 'lower', 'higher', 'nearest', 'midpoint']
import scipy.stats
for i in interpol:
print(i.upper())
print(f'IQR: {scipy.stats.iqr(df,interpolation=i)}')Output
LINEAR
IQR: 4.0
LOWER
IQR: 4
HIGHER
IQR: 4
NEAREST
IQR: 4
MIDPOINT
IQR: 4.0ANCOVA: Analysis of Covariance with python
ANCOVA is an extension of ANOVA (Analysis of Variance) that combines blocks of regression analysis and ANOVA. Which makes it Analysis of Covariance.
Learn Python The Fun Way
What if we learn topics in a desirable way!! What if we learn to write Python codes from gamers data !!
Meet the most efficient and intelligent AI assistant : NotebookLM
Start using NotebookLM today and embark on a smarter, more efficient learning journey!
Break the ice
This can be a super guide for you to start and excel in your data science career.
SQL quiz : HAVING
Solve the task by completing the SQL script
Quiz on LAG function
Learn about LAG function in SQL and solve the quiz.
Quiz on Python Function basics
fill in the blanks to complete the code.
Quiz on pandas basics
Brush up on your pandas basics knowledge. Drag and drop quizzes.
Numpy Excercise
Improve your analytical skills by practicing the following tasks
Random Forest with python
Random forest trees combine multiple decision trees to obtain an output. And it is flexible enough to adapt to Classification and Regression.Â
Standard Deviation
In measures of dispersion, the standard deviation is one of the prominent tools to calculate the dispersion of the data
Methods Of Dispersion
Let’s learn to calculate the spread of the data and measure it. with Absolute measures and Relative measures
Interquartile Range
Interquartile range is the difference between first and last quarters in a series of numbers. A Quartile range means a four-partition series of numbers.
IQR with Excel and python
In this article, we will learn how to utilize the functionalities provided by excel and python libraries to calculate IQR,
Points You Earned
0 distinction_points
python_points 0
0 Solver points
Leave a Reply
You must be logged in to post a comment.