Principal Component Analysis

Principal Component Analysis

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1. What is Principal Component Analysis

Let's take a look at PCA (Principal Component Analysis) from afar. In this section, you will learn what PCA is, why this data processing method is needed and see the real problems it solves.

Practical Application of PCA

Mathematical Idea

Examples of Real Problems

How to Explain the Obtained Results?

2. Basic Concepts of PCA

Learn about the design of the PCA algorithm. This section will show each stage in detail and simply.

Standardization

Covariance Matrix

Eigenvalues and Eigenvectors

Feature Vector and Principal Components

Seeing the Big Picture

3. Model Building

Set up your first PCA model using the Python library and solve the challenge provided for us.

Scikit-learn for PCA

Explore Dataset

Fit Data into the Model

4. Results Analysis

It's time to find out how we can explain the results. What do the first, second and third components tell us? What can we use the data for in the future?

Explain Resulting Components

What’s after?

Data Compression

Noise Reduction

Image Compression

Course Content

Principal Component Analysis

Principal Component Analysis

1. What is Principal Component Analysis

Introduction Practical Application of PCA Mathematical Idea Examples of Real Problems How to Explain the Obtained Results?

2. Basic Concepts of PCA

Standardization Covariance Matrix Eigenvalues and Eigenvectors Feature Vector and Principal Components Seeing the Big Picture

3. Model Building

Scikit-learn for PCA Explore Dataset Fit Data into the Model Challenge

4. Results Analysis

Explain Resulting Components What’s after?Data Compression Noise Reduction Image Compression

Feature Vector and Principal Components

After we have our main components, we need to create a feature vector. Why do we need this new variable? At this stage, we decide whether to keep all components or discard those that have the least value. The feature vector is just a matrix of vectors from the remaining most significant components.

Thus, the creation of the feature vector is exactly the stage at which dataset dimensionality reduction occurs, because if we decide to keep only p principal components out of n, the final dataset will have only p dimensions.

We can reduce a matrix with 2 components to 1 component:

Finally, we have the main components and we can transform our data, i.e. reorient the data from the original axes to those represented by the principal components. This is implemented very simply by multiplying the feature vector by standardized data (the matrices must be transposed):

Quiz

From which dimension to which was the dataset in the image transferred?

Everything was clear?

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Section 2. Chapter 4

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