Numpy Concepts: Difference between revisions
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=<tt>Pseudorandom Number Generation</tt>= | =<tt>Pseudorandom Number Generation</tt>= | ||
{{Internal|NumPy_Pseudorandom_Number_Generation#Overview|Pseudorandom Number Generation}} | {{Internal|NumPy_Pseudorandom_Number_Generation#Overview|Pseudorandom Number Generation}} | ||
=<tt>Universal Functions</tt>= | |||
{{Internal|NumPy_Universal_Functions#Overview|Universal Functions}} |
Revision as of 19:52, 20 May 2024
External
Internal
Overview
NumPy is the short for Numerical Python. It provides data structures, algorithms and library glue needed for most scientific applications involving numerical data in Python. NumPy contains:
- A fast and efficient multidimensional array object
ndarray
. For numerical data, NumPy arrays are more efficient for storing and manipulating data than other built-in Python data structures. The reason is that NumPy stores data in continuous block of memory, independent of other built-in Python objects. Also, NumPy library or algorithms is written in C and can operate on this memory without any type checking or other overhead. - Functions for performing element-wise computations with arrays, and mathematical operations between arrays.
- Tools for reading and writing array-based datasets to disk.
- Linear algebra operations, Fourier transform, random number generation.
- A mature C API to enable Python extensions and native C or C++ code to access NumPy's data structures.
One of NumPy's primary uses is as a container for data to be passed between algorithms and libraries. NumPy is one of the most important foundational packages for numerical computing in Python and a dependency for Pandas.
NumPy does not provide time series manipulation, which is present in Pandas.
Import Convention
import numpy as np