import numpy as np
import matplotlib.pyplot as plt
plt.rcParams.update({
"font.family": "serif",
"font.serif": ["cmr10"],
"font.size": 22,
"lines.linewidth": 3})
hfont = {'fontname':'cmmi10'}
# Set up the figure
# Figsize as (x, y), real size of the graph independent of values in it
fig = plt.figure(figsize=(10, 10))
# ax = fig.gca()
# The range of x values for which an y value will be calculated (using func)
# Second parameter +stepsize because end is exclusive, start is inclusive
stepsize_x = 1
xrange = np.arange(-15, 15+stepsize_x, stepsize_x)
###########
# Subplot 1
###########
ax1 = plt.subplot(4, 2, 1)
# set the spacing between subplots
plt.subplots_adjust(wspace=0.5,
hspace=1.2)
# Set up stem plot lines/dots
markerline1, stemlines1, baseline1 = plt.stem(xrange, np.cos(xrange * (2 * np.pi * 0 / 4)), basefmt=' ')
plt.title(r'$\omega = \frac{2\pi0}{4}$', **hfont)
plt.xlabel(r'$n$', **hfont)
plt.ylabel(r'$\cos(\omega 0 n)$', **hfont)
# Set limits of x-axis equal to xrange
plt.xlim(xrange[0], xrange[-1])
# Set limits of y-axis manually
plt.ylim(-1.2, 1.2)
plt.grid()
############
# Subplot 2
############
ax2 = plt.subplot(4, 2, 2)
# Set up stem plot lines/dots
markerline2, stemlines2, baseline2 = plt.stem(xrange, np.sin(xrange * (2 * np.pi * 0 / 4)), basefmt=' ')
plt.title(r'$\omega = \frac{2\pi0}{4}$')
plt.xlabel(r'$n$')
plt.ylabel(r'$\sin(\omega n)$')
# Set limits of x-axis equal to xrange
plt.xlim(xrange[0], xrange[-1])
# Set limits of y-axis manually
plt.ylim(-1.2, 1.2)
plt.grid()
###########
# Subplot 3
###########
ax3 = plt.subplot(4, 2, 3)
# Set up stem plot lines/dots
markerline3, stemlines3, baseline3 = plt.stem(xrange, np.cos(xrange * (2 * np.pi * 1 / 4)), basefmt=' ')
plt.title(r'$\omega = \frac{2\pi1}{4}$')
plt.xlabel(r'$n$')
plt.ylabel(r'$\cos(\omega n)$')
# Set limits of x-axis equal to xrange
plt.xlim(xrange[0], xrange[-1])
# Set limits of y-axis manually
plt.ylim(-1.2, 1.2)
plt.grid()
############
# Subplot 4
############
ax4 = plt.subplot(4, 2, 4)
# Set up stem plot lines/dots
markerline4, stemlines4, baseline4 = plt.stem(xrange, np.sin(xrange * (2 * np.pi * 1 / 4)), basefmt=' ')
plt.title(r'$\omega = \frac{2\pi1}{4}$')
plt.xlabel(r'$n$')
plt.ylabel(r'$\sin(\omega n)$')
# Set limits of x-axis equal to xrange
plt.xlim(xrange[0], xrange[-1])
# Set limits of y-axis manually
plt.ylim(-1.2, 1.2)
plt.grid()
###########
# Subplot 5
###########
ax5 = plt.subplot(4, 2, 5)
# Set up stem plot lines/dots
markerline5, stemlines5, baseline5 = plt.stem(xrange, np.cos(xrange * (2 * np.pi * 2 / 4)), basefmt=' ')
plt.title(r'$\omega = \frac{2\pi2}{4}$')
plt.xlabel(r'$n$')
plt.ylabel(r'$\cos(\omega n)$')
# Set limits of x-axis equal to xrange
plt.xlim(xrange[0], xrange[-1])
# Set limits of y-axis manually
plt.ylim(-1.2, 1.2)
plt.grid()
############
# Subplot 6
############
ax6 = plt.subplot(4, 2, 6)
# Set up stem plot lines/dots
markerline6, stemlines6, baseline6 = plt.stem(xrange, np.sin(xrange * (2 * np.pi * 2 / 4)), basefmt=' ')
plt.title(r'$\omega = \frac{2\pi2}{4}$')
plt.xlabel(r'$n$')
plt.ylabel(r'$\sin(\omega n)$')
# Set limits of x-axis equal to xrange
plt.xlim(xrange[0], xrange[-1])
# Set limits of y-axis manually
plt.ylim(-1.2, 1.2)
plt.grid()
###########
# Subplot 7
###########
ax7 = plt.subplot(4, 2, 7)
# Set up stem plot lines/dots
markerline7, stemlines7, baseline7 = plt.stem(xrange, np.cos(xrange * (2 * np.pi * 3 / 4)), basefmt=' ')
plt.title(r'$\omega = \frac{2\pi3}{4}$')
plt.xlabel(r'$n$')
plt.ylabel(r'$\cos(\omega n)$')
# Set limits of x-axis equal to xrange
plt.xlim(xrange[0], xrange[-1])
# Set limits of y-axis manually
plt.ylim(-1.2, 1.2)
plt.grid()
############
# Subplot 8
############
ax8 = plt.subplot(4, 2, 8)
# Set up stem plot lines/dots
markerline8, stemlines8, baseline8 = plt.stem(xrange, np.sin(xrange * (2 * np.pi * 3 / 4)), basefmt=' ')
plt.title(r'$\omega = \frac{2\pi3}{4}$')
plt.xlabel(r'$n$')
plt.ylabel(r'$\sin(\omega n)$')
# Set limits of x-axis equal to xrange
plt.xlim(xrange[0], xrange[-1])
# Set limits of y-axis manually
plt.ylim(-1.2, 1.2)
plt.grid()
plt.show() Write, Run & Share Python code online using OneCompiler's Python online compiler for free. It's one of the robust, feature-rich online compilers for python language, supporting both the versions which are Python 3 and Python 2.7. Getting started with the OneCompiler's Python editor is easy and fast. The editor shows sample boilerplate code when you choose language as Python or Python2 and start coding.
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When ever you want to perform a set of operations based on a condition IF-ELSE is used.
if conditional-expression
#code
elif conditional-expression
#code
else:
#code
Indentation is very important in Python, make sure the indentation is followed correctly
For loop is used to iterate over arrays(list, tuple, set, dictionary) or strings.
mylist=("Iphone","Pixel","Samsung")
for i in mylist:
print(i)
While is also used to iterate a set of statements based on a condition. Usually while is preferred when number of iterations are not known in advance.
while condition
#code
There are four types of collections in Python.
List is a collection which is ordered and can be changed. Lists are specified in square brackets.
mylist=["iPhone","Pixel","Samsung"]
print(mylist)
Tuple is a collection which is ordered and can not be changed. Tuples are specified in round brackets.
myTuple=("iPhone","Pixel","Samsung")
print(myTuple)
Below throws an error if you assign another value to tuple again.
myTuple=("iPhone","Pixel","Samsung")
print(myTuple)
myTuple[1]="onePlus"
print(myTuple)
Set is a collection which is unordered and unindexed. Sets are specified in curly brackets.
myset = {"iPhone","Pixel","Samsung"}
print(myset)
Dictionary is a collection of key value pairs which is unordered, can be changed, and indexed. They are written in curly brackets with key - value pairs.
mydict = {
"brand" :"iPhone",
"model": "iPhone 11"
}
print(mydict)
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| Name | Description |
|---|---|
| NumPy | NumPy python library helps users to work on arrays with ease |
| SciPy | SciPy is a scientific computation library which depends on NumPy for convenient and fast N-dimensional array manipulation |
| SKLearn/Scikit-learn | Scikit-learn or Scikit-learn is the most useful library for machine learning in Python |
| Pandas | Pandas is the most efficient Python library for data manipulation and analysis |
| DOcplex | DOcplex is IBM Decision Optimization CPLEX Modeling for Python, is a library composed of Mathematical Programming Modeling and Constraint Programming Modeling |