Numpy from basics to advanced.pdf
2.4 MB
NumPy is an essential library in the world of data science, widely recognized for its efficiency in numerical computations and data manipulation. This powerful tool simplifies complex operations with arrays, offering a faster and cleaner alternative to traditional Python lists and loops.
The "Mastering NumPy" booklet provides a comprehensive walkthroughβfrom array creation and indexing to mathematical/statistical operations and advanced topics like reshaping and stacking. All concepts are illustrated with clear, beginner-friendly examples, making it ideal for anyone aiming to boost their data handling skills.
#NumPy #Python #DataScience #MachineLearning #AI #BigData #DeepLearning #DataAnalysis
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python_basics.pdf
212.3 KB
I've just compiled a set of clean and powerful Python Cheat Sheets to help beginners and intermediates speed up their coding workflow.
Whether you're brushing up on the basics or diving into data science, these sheets will save you time and boost your productivity.
Python Basics
Jupyter Notebook Tips
Importing Libraries
NumPy Essentials
Pandas Overview
Perfect for students, developers, and anyone looking to keep essential Python knowledge at their fingertips.
#Python #CheatSheets #PythonTips #DataScience #JupyterNotebook #NumPy #Pandas #MachineLearning #AI #CodingTips #PythonForBeginners
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NUMPY FOR DS.pdf
4.5 MB
Let's start at the top...
NumPy contains a broad array of functionality for fast numerical & mathematical operations in Python
The core data-structure within #NumPy is an ndArray (or n-dimensional array)
Behind the scenes - much of the NumPy functionality is written in the programming language C
NumPy functionality is used in other popular #Python packages including #Pandas, #Matplotlib, & #scikitlearn!
βοΈ Our Telegram channels: https://t.me/addlist/0f6vfFbEMdAwODBk
NumPy contains a broad array of functionality for fast numerical & mathematical operations in Python
The core data-structure within #NumPy is an ndArray (or n-dimensional array)
Behind the scenes - much of the NumPy functionality is written in the programming language C
NumPy functionality is used in other popular #Python packages including #Pandas, #Matplotlib, & #scikitlearn!
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Forwarded from Python Data Science Jobs & Interviews
In Python, NumPy is the cornerstone of scientific computing, offering high-performance multidimensional arrays and tools for working with themβcritical for data science interviews and real-world applications! π
By: @DataScienceQ π
#Python #NumPy #DataScience #CodingInterview #MachineLearning #ScientificComputing #DataAnalysis #Programming #TechJobs #DeveloperTips
import numpy as np
# Array Creation - The foundation of NumPy
arr = np.array([1, 2, 3])
zeros = np.zeros((2, 3)) # 2x3 matrix of zeros
ones = np.ones((2, 2), dtype=int) # Integer matrix
arange = np.arange(0, 10, 2) # [0 2 4 6 8]
linspace = np.linspace(0, 1, 5) # [0. 0.25 0.5 0.75 1. ]
print(linspace)
# Array Attributes - Master your data's structure
matrix = np.array([[1, 2, 3], [4, 5, 6]])
print(matrix.shape) # Output: (2, 3)
print(matrix.ndim) # Output: 2
print(matrix.dtype) # Output: int64
print(matrix.size) # Output: 6
# Indexing & Slicing - Precision data access
data = np.array([[1, 2, 3], [4, 5, 6], [7, 8, 9]])
print(data[1, 2]) # Output: 6 (row 1, col 2)
print(data[0:2, 1:3]) # Output: [[2 3], [5 6]]
print(data[:, -1]) # Output: [3 6 9] (last column)
# Reshaping Arrays - Transform dimensions effortlessly
flat = np.arange(6)
reshaped = flat.reshape(2, 3)
raveled = reshaped.ravel()
print(reshaped)
# Output: [[0 1 2], [3 4 5]]
print(raveled) # Output: [0 1 2 3 4 5]
# Stacking Arrays - Combine datasets vertically/horizontally
a = np.array([1, 2, 3])
b = np.array([4, 5, 6])
print(np.vstack((a, b))) # Vertical stack
# Output: [[1 2 3], [4 5 6]]
print(np.hstack((a, b))) # Horizontal stack
# Output: [1 2 3 4 5 6]
# Mathematical Operations - Vectorized calculations
x = np.array([1, 2, 3])
y = np.array([4, 5, 6])
print(x + y) # Output: [5 7 9]
print(x * 2) # Output: [2 4 6]
print(np.dot(x, y)) # Output: 32 (1*4 + 2*5 + 3*6)
# Broadcasting Magic - Operate on mismatched shapes
matrix = np.array([[1, 2, 3], [4, 5, 6]])
scalar = 10
print(matrix + scalar)
# Output: [[11 12 13], [14 15 16]]
# Aggregation Functions - Statistical power in one line
values = np.array([1, 5, 3, 9, 7])
print(np.sum(values)) # Output: 25
print(np.mean(values)) # Output: 5.0
print(np.max(values)) # Output: 9
print(np.std(values)) # Output: 2.8284271247461903
# Boolean Masking - Filter data like a pro
temperatures = np.array([18, 25, 12, 30, 22])
hot_days = temperatures > 24
print(temperatures[hot_days]) # Output: [25 30]
# Random Number Generation - Simulate real-world data
print(np.random.rand(2, 2)) # Uniform distribution
print(np.random.randn(3)) # Normal distribution
print(np.random.randint(0, 10, (2, 3))) # Random integers
# Linear Algebra Essentials - Solve equations like a physicist
A = np.array([[3, 1], [1, 2]])
b = np.array([9, 8])
x = np.linalg.solve(A, b)
print(x) # Output: [2. 3.] (Solution to 3x+y=9 and x+2y=8)
# Matrix inverse and determinant
print(np.linalg.inv(A)) # Output: [[ 0.4 -0.2], [-0.2 0.6]]
print(np.linalg.det(A)) # Output: 5.0
# File Operations - Save/load your computational work
data = np.array([[1, 2], [3, 4]])
np.save('array.npy', data)
loaded = np.load('array.npy')
print(np.array_equal(data, loaded)) # Output: True
# Interview Power Move: Vectorization vs Loops
# 10x faster than native Python loops!
def square_sum(n):
arr = np.arange(n)
return np.sum(arr ** 2)
print(square_sum(5)) # Output: 30 (0Β²+1Β²+2Β²+3Β²+4Β²)
# Pro Tip: Memory-efficient data processing
# Process 1GB array without loading entire dataset
large_array = np.memmap('large_data.bin', dtype='float32', mode='r', shape=(1000000, 100))
print(large_array[0:5, 0:3]) # Process small slice
By: @DataScienceQ π
#Python #NumPy #DataScience #CodingInterview #MachineLearning #ScientificComputing #DataAnalysis #Programming #TechJobs #DeveloperTips
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π‘ NumPy Tip: Efficient Filtering with Boolean Masks
Avoid slow Python loops for filtering data. Instead, create a "mask" array of
Code explanation: A NumPy array
#Python #NumPy #DataScience #CodingTips #Programming
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By: @CodeProgrammer β¨
Avoid slow Python loops for filtering data. Instead, create a "mask" array of
True/False values based on a condition. Applying this mask to your original array instantly selects only the elements where the mask is True, which is significantly faster.import numpy as np
# Create an array of data
data = np.array([10, 55, 8, 92, 43, 77, 15])
# Create a boolean mask for values greater than 50
high_values_mask = data > 50
# Use the mask to select elements
filtered_data = data[high_values_mask]
print(filtered_data)
# Output: [55 92 77]
Code explanation: A NumPy array
data is created. Then, a boolean array high_values_mask is generated, which is True for every element in data greater than 50. This mask is used as an index to efficiently extract and print only those matching elements from the original array.#Python #NumPy #DataScience #CodingTips #Programming
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By: @CodeProgrammer β¨
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