Just because you have a “hammer”, doesn’t mean that every problem you come across will be a “nail”.

The intelligent key thing is when you use the same hammer to solve what ever problem you came across. Like the same way when we indented to solve a datamining problem we will face so many issues but we can solve them by using python in a intelligent way.

In very next post I am going to wet your hands to solve one interesting datamining problem using python programming language. so in this post I am going to explain about some powerful Python weapons( packages )

Before stepping directly to Python packages, let me clear up any doubts you may have about why you should be using Python.

Why Python ?

We all know that python is powerful programming language, but what does that mean, exactly? What makes python a powerful programming language?

Python is Easy

Universally, Python has gained a reputation because of it’s easy to learn. The syntax of Python programming language is designed to be easily readable. Python has significant popularity in scientific computing. The people working in this field are scientists first, and programmers second.

Python is Efficient

Nowadays we working on bulk amount of data, popularly known as big data. The more data you have to process, the more important it becomes to manage the memory you use. Here Python will work very efficiently.

Python is Fast

We all know Python is an interpreted language, we may think that it is slow, but some amazing work has been done over the past years to improve Python’s performance. My point is that if you want to do high-performance computing, Python is a viable best option today.

Hope I cleared your doubt about “Why Python?”, so let me jump to Python Packages for data mining.

NumPy

About:

NumPy is the fundamental package for scientific computing with Python. NumPy is an extension to the Python programming language, adding support for large, multi-dimensional arrays and matrices, along with a large library of high-level mathematical functions to operate on these arrays. The ancestor of NumPy, Numeric, was originally created by Jim Hugunin with contributions from several other developers. In 2005, Travis Oliphant created NumPy by incorporating features of the competing Numarray into Numeric, with extensive modifications.

Original author(s) Travis Oliphant Developer(s) Community project Initial release As Numeric, 1995; as NumPy, 2006 Stable release 1.9.0 / 7 September 2014 ; 36 days ago Written in Python, C Operating system Cross-platform Type Technical computing License BSD-new license Website www.numpy.org

Installing numpy:

If Python is not installed in your computer please install it first.

Installing numpy in linux

Open your terminal and copy these commands:

sudo apt-get update

sudo apt-get install python-numpy



Sample numpy code for using reshape function

from numpy import * a = arange(12) a = a.reshape(3,2,2) print a

Script output

[[[ 0 1]

[ 2 3]]

[[ 4 5]

[ 6 7]]

[[ 8 9]

[10 11]]]

SciPy

About:

SciPy (pronounced “Sigh Pie”) is open-source software for mathematics, science, and engineering. The SciPy library depends on NumPy, which provides convenient and fast N-dimensional array manipulation. The SciPy library is built to work with NumPy arrays, and provides many user-friendly and efficient numerical routines such as routines for numerical integration and optimization. Together, they run on all popular operating systems, are quick to install, and are free of charge. NumPy and SciPy are easy to use, but powerful enough to be depended upon by some of the world’s leading scientists and engineers. If you need to manipulate numbers on a computer and display or publish the results, Scipy is the tool for the job.

Installing SciPy in linux

Open your terminal and copy these commands:

sudo apt-get update

sudo apt-get install python-scipy

Sample SciPy code

from scipy import special, optimize f = lambda x: -special.jv(3, x) sol = optimize.minimize(f, 1.0) x = linspace(0, 10, 5000) plot(x, special.jv(3, x), '-', sol.x, -sol.fun, 'o') savefig('plot.png', dpi=96)

Script output

Pandas

About:

Pandas is a Python package providing fast, flexible, and expressive data structures designed to make working with “relational” or “labeled” data both easy and intuitive. It aims to be the fundamental high-level building block for doing practical, real world data analysis in Python. Additionally, it has the broader goal of becoming the most powerful and flexible open source data analysis / manipulation tool available in any language. It is already well on its way toward this goal.

Pandas is well suited for many different kinds of data:

Tabular data with heterogeneously-typed columns, as in an SQL table or Excel spreadsheet.

Ordered and unordered (not necessarily fixed-frequency) time series data.

Arbitrary matrix data (homogeneously typed or heterogeneous) with row and column labels.

Any other form of observational / statistical data sets. The data actually need not be labeled at all to be placed into a pandas data structure.

Installing Pandas in Linux

Open your terminal and copy these commands:

sudo apt-get update

sudo apt-get install python-pandas

Sample Pandas code about Pandas Series

import pandas as pd values = np.array([2.0, 1.0, 5.0, 0.97, 3.0, 10.0, 0.0599, 8.0]) ser = pd.Series(values) print ser

Script output

0 2.0000

1 1.0000

2 5.0000

3 0.9700

4 3.0000

5 10.0000

6 0.0599

7 8.0000



Matplotlib

About:

matplotlib is a plotting library for the Python programming language and its NumPy numerical mathematics extension. It provides an object-oriented API for embedding plots into applications using general-purpose GUI toolkits like wxPython, Qt, or GTK+. There is also a procedural “pylab” interface based on a state machine (like OpenGL), designed to closely resemble that of MATLAB. SciPy makes use of matplotlib.

Installing Matplotlib in linux

Open your terminal and copy these commands:

sudo apt-get update

sudo apt-get install python-matplotlib

Sample Matplotlib code to Create Histograms

import numpy as np import matplotlib.mlab as mlab import matplotlib.pyplot as plt # example data mu = 100 # mean of distribution sigma = 15 # standard deviation of distribution x = mu + sigma * np.random.randn(10000) num_bins = 50 # the histogram of the data n, bins, patches = plt.hist(x, num_bins, normed=1, facecolor='green', alpha=0.5) # add a 'best fit' line y = mlab.normpdf(bins, mu, sigma) plt.plot(bins, y, 'r--') plt.xlabel('Smarts') plt.ylabel('Probability') plt.title(r'Histogram of IQ: $\mu=100$, $\sigma=15$') # Tweak spacing to prevent clipping of ylabel plt.subplots_adjust(left=0.15) plt.show()

Script output

Ipython

IPython is a command shell for interactive computing in multiple programming languages, originally developed for the Python programming language, that offers enhanced introspection, rich media, additional shell syntax, tab completion, and rich history. IPython currently provides the following features:

Powerful interactive shells (terminal and Qt-based).

A browser-based notebook with support for code, text, mathematical expressions, inline plots and other rich media.

Support for interactive data visualization and use of GUI toolkits.

Flexible, embeddable interpreters to load into one’s own projects.

Easy to use, high performance tools for parallel computing.

Installing IPython in linux

Open your terminal and copy these commands:

sudo apt-get update

sudo pip install ipython

Sample IPython code

This piece of code is to plot demonstrating the integral as the area under a curve

import numpy as np import matplotlib.pyplot as plt from matplotlib.patches import Polygon def func(x): return (x - 3) * (x - 5) * (x - 7) + 85 a, b = 2, 9 # integral limits x = np.linspace(0, 10) y = func(x) fig, ax = plt.subplots() plt.plot(x, y, 'r', linewidth=2) plt.ylim(ymin=0) # Make the shaded region ix = np.linspace(a, b) iy = func(ix) verts = [(a, 0)] + list(zip(ix, iy)) + [(b, 0)] poly = Polygon(verts, facecolor='0.9', edgecolor='0.5') ax.add_patch(poly) plt.text(0.5 * (a + b), 30, r"$\int_a^b f(x)\mathrm{d}x$", horizontalalignment='center', fontsize=20) plt.figtext(0.9, 0.05, '$x$') plt.figtext(0.1, 0.9, '$y$') ax.spines['right'].set_visible(False) ax.spines['top'].set_visible(False) ax.xaxis.set_ticks_position('bottom') ax.set_xticks((a, b)) ax.set_xticklabels(('$a$', '$b$')) ax.set_yticks([]) plt.show()

Script output

scikit-learn

The scikit-learn project started as scikits.learn, a Google Summer of Code project by David Cournapeau. Its name stems from the notion that it is a “SciKit” (SciPy Toolkit), a separately-developed and distributed third-party extension to SciPy. The original codebase was later extensively rewritten by other developers. Of the various scikits, scikit-learn as well as scikit-image were described as “well-maintained and popular” in November 2012.

Installing Scikit-learn in linux

Open your terminal and copy these commands

sudo apt-get update

sudo apt-get install python-sklearn

Sample Scikit-learn code

import matplotlib.pyplot as plt import numpy as np from sklearn import datasets, linear_model # Load the diabetes dataset diabetes = datasets.load_diabetes() # Use only one feature diabetes_X = diabetes.data[:, np.newaxis] diabetes_X_temp = diabetes_X[:, :, 2] # Split the data into training/testing sets diabetes_X_train = diabetes_X_temp[:-20] diabetes_X_test = diabetes_X_temp[-20:] # Split the targets into training/testing sets diabetes_y_train = diabetes.target[:-20] diabetes_y_test = diabetes.target[-20:] # Create linear regression object regr = linear_model.LinearRegression() # Train the model using the training sets regr.fit(diabetes_X_train, diabetes_y_train) # The coefficients print('Coefficients:

', regr.coef_) # The mean square error print("Residual sum of squares: %.2f" % np.mean((regr.predict(diabetes_X_test) - diabetes_y_test) ** 2)) # Explained variance score: 1 is perfect prediction print('Variance score: %.2f' % regr.score(diabetes_X_test, diabetes_y_test)) # Plot outputs plt.scatter(diabetes_X_test, diabetes_y_test, color='black') plt.plot(diabetes_X_test, regr.predict(diabetes_X_test), color='blue', linewidth=3) plt.xticks(()) plt.yticks(()) plt.show()

Script output

Coefficients:

[ 938.23786125]

Residual sum of squares: 2548.07

Variance score: 0.47

I have explained the packages which we are going to use in coming posts to solve some interesting problems.

Please leave your comment if you have any other Python data mining packages to add to this list.

Originally published here.

(Image credit: Thomas Hawk)