Too much of anything is good for nothing!

Picture this – you are working on a large-scale data science project. What happens when the given data set has too many variables? There are a few possible situations that you might come across. For instance, you find that most of the variables are correlated on analysis, and you become indecisive about what to do; hence you lose patience and decide to run a model on the whole data. This returns poor accuracy, and you feel terrible and start thinking of some strategic method to find a few important variables. That’s where Principal Component Analysis (PCA) is used.

Trust me, dealing with such situations isn’t as difficult as it sounds. This is the most common scenario in machine learning projects. Statistical techniques such as factor analysis and principal component analysis (PCA) help to overcome such difficulties. In this post, I’ve explained the concept of PCA. I’ve kept the explanation to be simple and informative. I’ve also demonstrated using this technique in R with interpretations for practical understanding.

- Step by step, you will learn the widely used technique of dimension reduction, which is Principal Component Analysis (
*PCA).* - You will also learn how to extract the important factors from the data with the help of PCA.
- At last, you will learn the Implementation of PCA in both R and Python.

- PCA vs LDA vs Factor Analysis
- What is Principal Component Analysis?
- What are Principal Components?
- How Principal Component Analysis (PCA) Work ?
- Principal Component Analysis (PCA) Examples
- Why is Normalization of Variables Necessary in Principal Component Analysis (PCA)?
- Implement PCA in R & Python (With Interpretation)
- Predictive Modeling With PCA Components
- Frequently Asked Questions

The table provides a concise comparison of three dimensionality reduction techniques: PCA, LDA, and Factor Analysis. It outlines their key characteristics, with PCA and Factor Analysis being unsupervised methods, and LDA being supervised. PCA and Factor Analysis aim to reduce dimensions and simplify data, while LDA seeks class separation.

Technique | Description |
---|---|

PCA (Principal Component Analysis) | Unsupervised dimension reduction technique. Reduces dimensions without considering class labels. Transforms correlated variables into linearly uncorrelated principal components that capture most of the data variance. Useful for data visualization and simplifying complex data. |

LDA (Linear Discriminant Analysis) | Supervised dimension reduction technique. Takes class labels into account to find a feature combination that maximizes class separation. Useful for classification tasks and finding discriminant features. |

Factor Analysis | Used to identify underlying, unmeasured variables (factors) that explain the variability across observed variables. Focuses on understanding latent structures in the data. Useful for revealing relationships and reducing dimensions based on these latent factors. |

**Principal Component Analysis (PCA)** is a powerful technique used in data analysis, particularly for reducing the dimensionality of datasets while preserving crucial information. It does this by transforming the original variables into a set of new, uncorrelated variables called **principal components**. Here’s a breakdown of PCA’s key aspects:

**Dimensionality Reduction**: PCA helps manage high-dimensional datasets by extracting essential information and discarding less relevant features, simplifying analysis.**Data Exploration and Visualization**: It plays a significant role in data exploration and visualization, aiding in uncovering hidden patterns and insights.**Linear Transformation**: PCA performs a linear transformation of data, seeking directions of maximum variance.**Feature Selection**: Principal components are ranked by the variance they explain, allowing for effective feature selection.**Data Compression**: PCA can compress data while preserving most of the original information.**Clustering and Classification**: It finds applications in clustering and classification tasks by reducing noise and highlighting underlying structure.**Advantages**: PCA offers linearity, computational efficiency, and scalability for large datasets.**Limitations**: It assumes data normality and linearity and may lead to information loss.**Matrix Requirements**: PCA works with symmetric correlation or covariance matrices and requires numeric, standardized data.**Eigenvalues and Eigenvectors**: Eigenvalues represent variance magnitude, and eigenvectors indicate variance direction.**Number of Components**: The number of principal components chosen determines the number of eigenvectors computed.

Let’s say we have a data set of dimension 300 (*n*) Ã— 50 (*p*). *n* represents the number of observations, and *p* represents the number of predictors. Since we have a large p = 50, there can be `p(p-1)/2`

scatter plots, i.e., more than 1000 plots possible to analyze the variable relationship. Wouldn’t it be a tedious job to perform exploratory analysis on this data?

In this case, it would be a lucid approach to select a subset of *p* *(p << 50)* predictor which captures so much information, followed by plotting the observation in the resultant low-dimensional space.

The image below shows the transformation of high-dimensional data (3 dimension) to low-dimensional data (2 dimension) using PCA. Not to forget, each resultant dimension is a linear combination of *p* features

A principal component (PCA) is a normalized linear combination of the original features in a data set. In the image above, *PC1* and *PC2* are the principal components. Let’s say we have a set of predictors as `XÂ¹, XÂ²...,X`

^{p}

The PCA in Python can be written as:

`ZÂ¹ = Î¦Â¹Â¹XÂ¹ + Î¦Â²Â¹XÂ² + Î¦Â³Â¹XÂ³ + .... +`

Î¦^{p}`Â¹X`

^{p}

where,

- ZÂ¹ is the first principal component
`Î¦`

is the loading vector comprising loadings (^{p}Â¹`Î¦Â¹, Î¦Â²..`

) of the first principal component. The loadings are constrained to a sum of squares equals to 1. This is because a large magnitude of loadings may lead to a large variance. It also defines the direction of the principal component (ZÂ¹), along which data varies the most. It results in a line in*p*dimensional space, which is closest to the*n*observations. Closeness is measured using average squared euclidean distance.`XÂ¹..X`

are normalized predictors. Normalized predictors have mean values equal to zero and standard deviations equal to one.^{p}

The first principal component is a linear combination of original predictor variables that captures the data set’s maximum variance. It determines the direction of highest variability in the data. Larger the variability captured in the first component, larger the information captured by component. No other component can have variability higher than first principal component.

The first principal component results in a line that is closest to the data, i.e., it minimizes the sum of squared distance between a data point and the line.

Similarly, we can compute the second principal component also.

`ZÂ²`

)The second principal component is also a linear combination of original predictors, which captures the remaining variance in the data set and is uncorrelated with `ZÂ¹`

. In other words, the correlation between first and second components should be zero. It can be represented as:

`ZÂ² = Î¦Â¹Â²XÂ¹ + Î¦Â²Â²XÂ² + Î¦Â³Â²XÂ³ + .... + Î¦`

^{p2}`X`

^{p}

If the two components are uncorrelated, their directions should be orthogonal (image below). This image is based on simulated data with 2 predictors. Notice the direction of the components; as expected, they are orthogonal. This suggests the correlation b/w these components is zero.

All succeeding principal component follows a similar concept, i.e., they capture the remaining variation without being correlated with the previous component. In general, for *n Ã— p* dimensional data, min(*n-1, p)* principal component can be constructed.

The directions of these components are identified unsupervised; i.e., the response variable(Y) is not used to determine the component direction. Therefore, it is an unsupervised approach.

*Note: Partial least square (PLS) is a supervised alternative to PCA. PLS assigns a higher weight to variables that are strongly related to response variable to determine principal components.*

**Standardize the Data**If the features of your dataset are on different scales, it’s essential to standardize them (subtract the mean and divide by the standard deviation).

**Compute the Covariance Matrix**Calculate the covariance matrix for the standardized dataset.

**Compute Eigenvectors and Eigenvalues**Find the eigenvectors and eigenvalues of the covariance matrix. The eigenvectors represent the directions of maximum variance, and the corresponding eigenvalues indicate the magnitude of variance along those directions.

**Sort Eigenvectors by Eigenvalues**Sort the eigenvectors based on their corresponding eigenvalues in descending order.

**Choose Principal Components**Select the top k eigenvectors (principal components) where k is the desired dimensionality of the reduced dataset.

**Transform the Data**Multiply the original standardized data by the selected principal components to obtain the new, lower-dimensional representation of the data.

**PCA in Python**

```
import numpy as np
from sklearn.decomposition import PCA
from sklearn.preprocessing import StandardScaler
import matplotlib.pyplot as plt
# Example Data
np.random.seed(42)
X = np.random.rand(100, 3) # 100 samples with 3 features
# Step 1: Standardize the Data
scaler = StandardScaler()
X_std = scaler.fit_transform(X)
# Step 2-5: PCA
pca = PCA()
X_pca = pca.fit_transform(X_std)
# Plot Explained Variance Ratio
explained_var_ratio = pca.explained_variance_ratio_
cumulative_var_ratio = np.cumsum(explained_var_ratio)
plt.plot(range(1, len(cumulative_var_ratio) + 1), cumulative_var_ratio, marker='o')
plt.xlabel('Number of Principal Components')
plt.ylabel('Cumulative Explained Variance Ratio')
plt.title('Explained Variance Ratio vs. Number of Principal Components')
plt.show()
```

- Image Compression: It reduces image dimensionality for efficient storage without losing critical information.
- Genomic Data Analysis: PCA identifies patterns in gene expression data, aiding in disease research.
- Financial Data Analysis: It analyzes covariance in asset returns for portfolio optimization.
- Spectral Analysis: PCA helps in signal processing to identify dominant spectral features.
- Customer Segmentation: It clusters customers based on behavior for targeted marketing.

The principal components are supplied with a normalized version of the original predictors. This is because the original predictors may have different scales. For example: Imagine a data set with variables measuring units as gallons, kilometers, light years, etc. The scale of variances in these variables will obviously be large.

Performing PCA on un-normalized variables will lead to exponentially large loadings for variables with high variance. In turn, this will lead to the dependence of a principal component on the variable with high variance. This is undesirable.

As shown in the image below, PCA was run on a data set twice (with unscaled and scaled predictors). This data set has ~40 variables. You can see a variable Item_MRP dominates first principal component and a variable Item_Weight dominates the second principal component. This domination prevails due to high value of variance associated with a variable. When the variables are scaled, we get a much better representation of variables in 2D space.

How many principal components to choose from the original dataset? I could dive deep into theory, but it would be better to answer these questions practically.

For this demonstration, I’ll be using the data set from Big Mart Prediction Challenge III.

Remember, Principal Component Analysis can be applied only to numerical data. Therefore, if the data have categorical variables, they must be converted to numerical ones. Also, make sure you have done the basic data cleaning prior to implementing this technique.

Let’s quickly finish with initial data loading and cleaning steps:

`#directory path`

` > path <- ".../Data/Big_Mart_Sales"`

`#set working directory`

` > setwd(path)`

`#load train and test file`

` > train <- read.csv("train_Big.csv")`

` > test <- read.csv("test_Big.csv")`

`#add a column`

` > test$Item_Outlet_Sales <- 1`

`#combine the data set`

` > combi <- rbind(train, test)`

`#impute missing values with median`

` > combi$Item_Weight[is.na(combi$Item_Weight)] <- median(combi$Item_Weight, na.rm = TRUE)`

`#impute 0 with median`

` > combi$Item_Visibility <- ifelse(combi$Item_Visibility == 0, median(combi$Item_Visibility), combi$Item_Visibility)`

`#find mode and impute`

` > table(combi$Outlet_Size, combi$Outlet_Type)`

` > levels(combi$Outlet_Size)[1] <- "Other"`

Till here, we’ve imputed missing values. Now we are left with removing the dependent (response) variable and other identifier variables( if any). As we said above, we are practicing an unsupervised learning technique; hence response variable must be removed.

```
#remove the dependent and identifier variables
> my_data <- subset(combi, select = -c(Item_Outlet_Sales, Item_Identifier, Outlet_Identifier))
```

Let’s check the available variables ( a.k.a predictors) in the data set.

```
#check available variables
> colnames(my_data)
```

Since PCA works on numeric variables, let’s see if we have any variables other than numeric.

```
#check variable class
> str(my_data)
'data.frame': 14204 obs. of 9 variables:
$ Item_Weight : num 9.3 5.92 17.5 19.2 8.93 ...
$ Item_Fat_Content : Factor w/ 5 levels "LF","low fat",..: 3 5 3 5 3 5 5 3 5 5 ...
$ Item_Visibility : num 0.016 0.0193 0.0168 0.054 0.054 ...
$ Item_Type : Factor w/ 16 levels "Baking Goods",..: 5 15 11 7 10 1 14 14 6 6 ...
$ Item_MRP : num 249.8 48.3 141.6 182.1 53.9 ...
$ Outlet_Establishment_Year: int 1999 2009 1999 1998 1987 2009 1987 1985 2002 2007 ...
$ Outlet_Size : Factor w/ 4 levels "Other","High",..: 3 3 3 1 2 3 2 3 1 1 ...
$ Outlet_Location_Type : Factor w/ 3 levels "Tier 1","Tier 2",..: 1 3 1 3 3 3 3 3 2 2 ...
$ Outlet_Type : Factor w/ 4 levels "Grocery Store",..: 2 3 2 1 2 3 2 4 2 2 ...
```

Sadly, 6 out of 9 variables are categorical in nature. We have some additional work to do now. We’ll convert these categorical variables into numeric ones using one hot encoding.

```
#load library
> library(dummies)
#create a dummy data frame
> new_my_data <- dummy.data.frame(my_data, names = c("Item_Fat_Content","Item_Type",
"Outlet_Establishment_Year","Outlet_Size",
"Outlet_Location_Type","Outlet_Type"))
```

To check if we now have a data set of integer values, simply write:

`#check the data set`

`> str(new_my_data)`

And we now have all the numerical values. Let’s divide the data into test and train.

```
#divide the new data
> pca.train <- new_my_data[1:nrow(train),]
> pca.test <- new_my_data[-(1:nrow(train)),]
```

We can now go ahead with PCA.

The base R function prcomp() is used to perform PCA. By default, it centers the variable to have a mean equal to zero. With parameter `scale. = T`

, we normalize the variables to have a standard deviation equal to 1.

```
#principal component analysis
> prin_comp <- prcomp(pca.train, scale. = T)
> names(prin_comp)
[1] "sdev" "rotation" "center" "scale" "x"
```

These refers to respective mean and standard deviation of the variables that are used for normalization prior to implementing PCA

```
#outputs the mean of variables
prin_comp$center
#outputs the standard deviation of variables
prin_comp$scale
```

The rotation measure provides the principal component loading. Each column of rotation matrix contains the principal component loading vector. This is the most important measure we should be interested in.

`> prin_comp$rotation`

This returns 44 principal component loadings. Is that correct? Absolutely. The maximum number of principal component loadings in a data set is a minimum of (n-1, p). Let’s look at the first 4 principal components and first 5 rows.

```
> prin_comp$rotation[1:5,1:4]
PC1 PC2 PC3 PC4
Item_Weight 0.0054429225 -0.001285666 0.011246194 0.011887106
Item_Fat_ContentLF -0.0021983314 0.003768557 -0.009790094 -0.016789483
Item_Fat_Contentlow fat -0.0019042710 0.001866905 -0.003066415 -0.018396143
Item_Fat_ContentLow Fat 0.0027936467 -0.002234328 0.028309811 0.056822747
Item_Fat_Contentreg 0.0002936319 0.001120931 0.009033254 -0.001026615
```

To compute the principal component score vector, we don’t need to multiply the loading with data. Rather, the matrix x has the principal component score vectors in an 8523 Ã— 44 dimension.

`> dim(prin_comp$x) `

[1] 8523 44

Let’s plot the resultant principal components.

The parameter `scale = 0`

ensures that arrows are scaled to represent the loadings. To infer from the image above, focus on this graph’s extreme ends (top, bottom, left, right).

We infer that the first principal component corresponds to Outlet_TypeSupermarket, Outlet_Establishment_Year 2007. Similarly, it can be said that the second component corresponds to a measure of Outlet_Location_TypeTier1, Outlet_Sizeother. For the exact measure of a variable in a component, you should look at rotation matrix(above) again.

This function also provides the facility to compute standard deviation of each principal component. *sdev* refers to the standard deviation of principal components.

```
#compute standard deviation of each principal component
> std_dev <- prin_comp$sdev
#compute variance
> pr_var <- std_dev^2
#check variance of first 10 components
> pr_var[1:10]
[1] 4.563615 3.217702 2.744726 2.541091 2.198152 2.015320 1.932076 1.256831
[9] 1.203791 1.168101
```

We aim to find the components which explain the maximum variance. This is because, we want to retain as much information as possible using these components. So, higher is the explained variance, higher will be the information contained in those components.

To compute the proportion of variance explained by each component, we simply divide the variance by sum of total variance. This results in:

```
#proportion of variance explained
> prop_varex <- pr_var/sum(pr_var)
> prop_varex[1:20]
[1] 0.10371853 0.07312958 0.06238014 0.05775207 0.04995800 0.04580274
[7] 0.04391081 0.02856433 0.02735888 0.02654774 0.02559876 0.02556797
[13] 0.02549516 0.02508831 0.02493932 0.02490938 0.02468313 0.02446016
[19] 0.02390367 0.02371118
```

This shows that first principal component explains 10.3% variance. Second component explains 7.3% variance. Third component explains 6.2% variance and so on. So, how do we decide how many components should we select for modeling stage ?

The answer to this question is provided by a scree plot. A scree plot is used to access components or factors which explains the most of variability in the data. It represents values in descending order.

```
#scree plot
> plot(prop_varex, xlab = "Principal Component",
ylab = "Proportion of Variance Explained",
type = "b")
```

The plot above shows that ~ 30 components explains around 98.4% variance in the data set. In order words, using PCA we have reduced 44 predictors to 30 without compromising on explained variance. This is the power of PCA> Let’s do a confirmation check, by plotting a cumulative variance plot. This will give us a clear picture of number of components.

`#cumulative scree plot`

`> plot(cumsum(prop_varex), xlab = "Principal Component",`

` ylab = "Cumulative Proportion of Variance Explained",`

` type = "b")`

This plot shows that 30 components result in a variance close to ~ 98%. Therefore, in this case, we’ll select the number of components as 30 [PC1 to PC30] and proceed to the modeling stage. This completes the steps to implement PCA on train data. For modeling, we’ll use these 30 components as predictor variables and follow the normal procedures.

This plot shows that 30 components result in a variance close to ~ 98%. Therefore, in this case, we’ll select the number of components as 30 [PC1 to PC30] and proceed to the modeling stage. This completes the steps to implement PCA on train data. For modeling, we’ll use these 30 components as predictor variables and follow the normal procedures.

Principal Component Analysis (PCA) is used along with machine learning algorithms for predictive modeling.

After we’ve performed PCA on the training set, let’s now understand the process of predicting test data using these components. The process is simple. Just like we’ve obtained PCA components on the training set, we’ll get another bunch of components on the testing set. Finally, we train the model.

But, few important points to understand:

- We should not combine the train and test set to obtain PCA components of the whole data at once, as this would violate the assumption of generalization since the test data would get ‘leaked’ into the training set. In other words, the test data set would no longer remain ‘unseen’. Eventually, this will hammer down the generalization capability of the model.
- We should not perform PCA on test and train data sets separately because the resultant vectors from the train and test PCAs will have different directions (due to unequal variance). Due to this, we’ll end up comparing data registered on different axes. Therefore, the resulting train and test data vectors should have same axes.

We should do exactly the same transformation to the test set as we did to the training set, including the center and scaling feature. Let’s do it in R:

`#add a training set with principal components`

`> train.data <- data.frame(Item_Outlet_Sales = train$Item_Outlet_Sales, prin_comp$x)`

`#we are interested in first 30 PCAs`

`> train.data <- train.data[,1:31]`

`#run a decision tree`

`> install.packages("rpart")`

`> library(rpart)`

`> rpart.model <- rpart(Item_Outlet_Sales ~ .,data = train.data, method = "anova")`

`> rpart.model`

`#transform test into PCA`

`> test.data <- predict(prin_comp, newdata = pca.test)`

`> test.data <- as.data.frame(test.data)`

`#select the first 30 components`

`> test.data <- test.data[,1:30]`

`#make prediction on test data`

`> rpart.prediction <- predict(rpart.model, test.data)`

`#For fun, finally check your score of leaderboard`

`> sample <- read.csv("SampleSubmission_TmnO39y.csv")`

`> final.sub <- data.frame(Item_Identifier = sample$Item_Identifier, Outlet_Identifier = sample$Outlet_Identifier, Item_Outlet_Sales = rpart.prediction)`

`> write.csv(final.sub, "pca.csv",row.names = F)`

That’s the complete modeling process after PCA extraction. I’m sure you wouldn’t be happy with your leaderboard rank after you upload the solution. Try using random forest!

To implement PCA in python, import PCA from sklearn library. The interpretation remains same as explained for R users above. Of course, the result is some as derived after using R. The data set used for Python is a cleaned version where missing values have been imputed, and categorical variables are converted into numeric. The modeling process remains same, as explained for R users above.

`import numpy as np`

` from sklearn.decomposition import PCA`

` import pandas as pd`

` import matplotlib.pyplot as plt`

` from sklearn.preprocessing import scale`

` %matplotlib inline`

`#Load data set`

` data = pd.read_csv('Big_Mart_PCA.csv')`

`#convert it to numpy arrays`

` X=data.values`

`#Scaling the values`

` X = scale(X)`

`pca = PCA(n_components=44)`

`pca.fit(X)`

`#The amount of variance that each PC explains`

` var= pca.explained_variance_ratio_`

`#Cumulative Variance explains`

` var1=np.cumsum(np.round(pca.explained_variance_ratio_, decimals=4)*100)`

`print var1`

` [ 10.37 17.68 23.92 29.7 34.7 39.28 43.67 46.53 49.27`

` 51.92 54.48 57.04 59.59 62.1 64.59 67.08 69.55 72.`

` 74.39 76.76 79.1 81.44 83.77 86.06 88.33 90.59 92.7`

` 94.76 96.78 98.44 100.01 100.01 100.01 100.01 100.01 100.01`

` 100.01 100.01 100.01 100.01 100.01 100.01 100.01 100.01]`

`plt.plot(var1`

)

```
#Looking at above plot I'm taking 30 variables
pca = PCA(n_components=30)
pca.fit(X)
X1=pca.fit_transform(X)
print X1
```

For more information on PCA in python, visit scikit learn documentation.

This brings me to the end of this Principal Component Analysis tutorial. Without delving deep into mathematics, I’ve tried to familiarize you with the most important concepts required to use this technique. It’s simple but needs special attention when deciding the number of components. Practically, we should strive to retain only the first few k components. The idea behind PCA is to construct some principal components (Z << Xp) that satisfactorily explain most of the data’s variability and relationship with the response variable.

This brings me to the end of this Principal Component Analysis tutorial. Without delving deep into mathematics, I’ve tried to make you familiar with the most important concepts required to use this technique. It’s simple but needs special attention when deciding the number of components. Practically, we should strive to retain only the first few k components. The idea behind PCA is to construct some principal components (Z << Xp) which satisfactorily explain most of the data’s variability and relationship with the response variable.

**Key Takeaways **

- Principal Component Analysis (PCA) is used to overcome feature redundancy in a data set. These features are low dimensional in nature. These features, a.k.a components, are a result of normalized linear combinations of original predictor variables.
- The first component has the highest variance, followed by second, third, and so on. The components must be uncorrelated (remember orthogonal direction ?). See above.
- Normalizing data becomes extremely important when the predictors are measured in different units.PCA works best on data sets having 3 or higher dimensions. Because, with higher dimensions, it becomes increasingly difficult to make interpretations from the resultant data cloud.

A. Use PCA when you have high-dimensional data to reduce its dimensionality while preserving most of the variance, simplifying analysis and visualization.

A. PCA analysis is utilized for dimensionality reduction, simplifying high-dimensional datasets while preserving essential information, speeding up computation, and aiding in data visualization and understanding.

A. In finance, PCA can be used to analyze a portfolio of stocks by identifying the key factors influencing their returns.

A. Standardize data

B.Compute Covariance Matrix

C.Eigendecomposition

D.Select Principal Components

E.Project Data

PCA analysis helps interpret data structure by identifying directions where data varies most. Each principal component captures a portion of the data’s overall variance, aiding in visualization, analysis, and dimensionality reduction.

Lorem ipsum dolor sit amet, consectetur adipiscing elit,

Become a full stack data scientist
##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

##

Understanding Cost Function
Understanding Gradient Descent
Math Behind Gradient Descent
Assumptions of Linear Regression
Implement Linear Regression from Scratch
Train Linear Regression in Python
Implementing Linear Regression in R
Diagnosing Residual Plots in Linear Regression Models
Generalized Linear Models
Introduction to Logistic Regression
Odds Ratio
Implementing Logistic Regression from Scratch
Introduction to Scikit-learn in Python
Train Logistic Regression in python
Multiclass using Logistic Regression
How to use Multinomial and Ordinal Logistic Regression in R ?
Challenges with Linear Regression
Introduction to Regularisation
Implementing Regularisation
Ridge Regression
Lasso Regression

Introduction to Stacking
Implementing Stacking
Variants of Stacking
Implementing Variants of Stacking
Introduction to Blending
Bootstrap Sampling
Introduction to Random Sampling
Hyper-parameters of Random Forest
Implementing Random Forest
Out-of-Bag (OOB) Score in the Random Forest
IPL Team Win Prediction Project Using Machine Learning
Introduction to Boosting
Gradient Boosting Algorithm
Math behind GBM
Implementing GBM in python
Regularized Greedy Forests
Extreme Gradient Boosting
Implementing XGBM in python
Tuning Hyperparameters of XGBoost in Python
Implement XGBM in R/H2O
Adaptive Boosting
Implementing Adaptive Boosing
LightGBM
Implementing LightGBM in Python
Catboost
Implementing Catboost in Python

Introduction to Clustering
Applications of Clustering
Evaluation Metrics for Clustering
Understanding K-Means
Implementation of K-Means in Python
Implementation of K-Means in R
Choosing Right Value for K
Profiling Market Segments using K-Means Clustering
Hierarchical Clustering
Implementation of Hierarchial Clustering
DBSCAN
Defining Similarity between clusters
Build Better and Accurate Clusters with Gaussian Mixture Models

Introduction to Machine Learning Interpretability
Framework and Interpretable Models
model Agnostic Methods for Interpretability
Implementing Interpretable Model
Understanding SHAP
Out-of-Core ML
Introduction to Interpretable Machine Learning Models
Model Agnostic Methods for Interpretability
Game Theory & Shapley Values

Deploying Machine Learning Model using Streamlit
Deploying ML Models in Docker
Deploy Using Streamlit
Deploy on Heroku
Deploy Using Netlify
Introduction to Amazon Sagemaker
Setting up Amazon SageMaker
Using SageMaker Endpoint to Generate Inference
Deploy on Microsoft Azure Cloud
Introduction to Flask for Model
Deploying ML model using Flask

Excellent Manish

Your appreciation means a lot. Thank you Tuhin Sir :)

Hi Manish, Information given about PCA in your article was very comprehensive as you have covered both the theoretical and the implementation part very well. It was fun and simple to understand too. Can you please write a similar one for Factor Analysis? How is it different from PCA and how to decide on the method of dimensional reduction case to case. Thanks

Thanks Surobhi ! I already have it in my plan to write soon one detailed post on Factor Analysis. Wish me luck!

This is good explanation Manish and thank you for sharing it. Quick question, model created using these 30pca will have all 50 independent variable but if I want to figure out what among those 50 independent variables which are most critical one then how we figure that so that we can build model using those specific variables. Will appreciate your help. Thanks

Hello For model building, we'll use the resultant 30 components as independent variables. Remember, each component is a vector comprising of principal component score derived from each predictor variable (in this case we have 50). Check prin_comp$rotation for principal component scores in each vector. This technique is used to shrink the dimension of a data set such that it becomes easier to analyze, visualize and interpret. By 'critical', I assume you are talking about measuring variable importance. If that's the case, you can look for p values, t statistics in regression. For variable selection, regression is equipped with various approaches such as forward selection, backward selection, step wise selection etc.

Really informative Manish, Also variables derived from PCA can be used for Regression analysis. Regression analysis with PCA gives a better prediction and less error.

Rightly said. PCA when used for regression takes a form of supervised approach known as PLS (partial least squares). In PLS, the response variable is used for identification of principal components.

Agreed. PCA with lm has smaller RMSE as compared to PCA with Randomforest

I have used PCA recently in one projects, and would like to add few points: -PCA reduce the dimension but the the result is not very intuitive, as each PCs are combination of all the original variables. So use 'Factor Analysis' (Factor Rotation) on top of PCA to get a better relationship between PCs (rather Factors) and original Variable, this result was brilliant in an Insurance data. -If you have perfectly correlated variables (A & B) then also PCA will not suggest you to drop one, rather it will suggest to use a combination of these two (A+B), but off course it will reduce the dimension -This is different from feature selection, don't mix these two concept -There is a concept of 'Nonlinear PCA' which helps to include non Numeric values as well. -If you want to reduce the dimension (or numbers) of predictors (X) remember PCA does not consider response (Y) while reducing the dimension, your original variables may be (??) a better predictors.

Thanks a lot Debarshi. These are so much helpful.

Hi Debarshi, Can you shed some light on Factor Rotation? I have considered PCA or simple correlation matrix approach to identify correlation among variables. Then at regression stage I have used VIF.

Good One

Hi Manish, Another good article! I have always found it difficult to explain the principle components to business users. Would really appreciate, if you also write how do you explain the PCA to business users... What general questions you get from business users and how to handle those. Thanks

I understand there is a PCA for qualitative data ... could some one provide me with a good intutive resource for suvh?

Hi Manish, The article is very helpful. While we normalize the data for numeric variables, do we need to remove outliers if any exists in the data before performing PCA? Also looks like , implementation of final model in production is quite tedious, as we always have to compute components prior scoring. Thanks, Krishna

Hello Also mentioned in the article, data cleaning (removal of outliers, imputing missing values) are important prior to implementing principal component analysis. Such things only adds noise and inconsistency in the data. Hence, it is a good practice to sort them out first. I beg to differ on this procedure being 'tedious'. For the sake of understanding, I've explained each and every step used in this technique, may be this makes it tedious. However, if you think you have understood it correctly, just pick the important commands (codes) and get to the scree plot stage in no time.

nice one explanation

Hi Manish, while running the command >prin_comp <- prcomp(new_my_data, scale. = T) it giving error "Error in svd(x, nu = 0) : infinite or missing values in 'x'" how to rectify it.... BTW a GREAT article.....

Hello This error says "Your data set has missing values. Please Impute". To rectify, run the code once again where I dealt with missing values. Good Luck!

Hi Manish, Great article. I am new to R & this provides a very clear implementation obviously. I just had one quick question though. The 30 components that we will be using for further analysis which data frame is that stored in? If not stored (for the purpose of this illustration) how can I create a data frame containing the 30 components & their scores that we can use further? Thanks Again!

Hello, very good article, but there seems to be a typo at the end of this line: "For Python Users: To implement PCA in python, simply import PCA from sklearn library. The interpretation remains same as explained for R users above. Ofcourse, " "Ofcourse" should be "Of course".

Good article

Hi Manish, first of all your article is super cool for real. But every single tutorial about PCA talks about only extracting the important features from the data frame. No where i have come across they are talking about how we build a model with the extracted important PCA components. Since I am new to R I would love to see you explain it in R . Consider that I am handling a classification problem Data frame called train that has columns Var1, Var2, Var3.........Var19 , output The output column is the classifier(the one I want to predict in my test dataset) with features Var1... VAr19 here are my questions I remove the output variable and apply prcomp to the remaining dataset(new_dataset) How do I merge the output variable to the PCA components ? Consider am trying to use simple logistic regression Logmodel = glm(output~. data= new_dataset) Predict (Logmodel, newdata= testdata) is this correct ? should I apply the PCA to the test data too ?

Hello Thanish, In my understanding, you combine the training and testing data to eliminate the missing values and initial operations. Then this combined data frame is used to generate the PCA components. Each row of this PCA component refers to the corresponding output value (total number of rows being equal to number of rows of training data + number of rows of testing data). So while building the model all you can do is split the data frame in training and testing (by simply using subset function). The reason for the ith value of any PCA component correspond the ith value of output is because different principal component loadings are multiplied with the ith value of original variables.

Hi, I am also not able to find any help on using these extracted principal components to build a predictive model.

Hi Manish, Thanks for the informative article. I have used PCA in SAS during scorecard development and it suggested to drop way too many variables than what I would have preferred to (I prefer to keep a few vars from each var category atleast to start with). Even after adjusting the eigen value threshold the number of vars being sacrificed was a lot. So I ended up using a simple correlation matrix approach which selects and retains highest IV variable from a group of correlated vars based on the correlation matrix with a 80% or 70% correlation threshold. Then at the regression stage I used VIF option to capture multi collinearity.

Very nice article and quite informative. Thanks a lot for making us aware of variable reduction technique. It'll be very good if you can further show how these 30 components can be used for modelling? An example will be very good to know.

Hi Manish can please also explain me how do you use those components to create a model and then predict. I would love to see the code for building the model and prediction in R. Because every tutorial I see they explain only till the point of extracting the components and nobody proceeds further, that is were I am struck. Kindly help me with that.

Hello Manish, This is really great article. i learned a lot from this article. Can you please write a article on selection of logistic vs decision trees vs bagging vs svm for a given dataset?How to select which method is good for certain kind of dataset?

I never usually respond to blog posts or articles but I feel sufficiently impressed (and grateful!) to do so here. Thank you so much for a well structured breakdown of PCA, taking the reader through, step by step, the technique used and the underlying rationale.

Is it ok if I less 10 PCAs in stead of 44 as an o/p?

Hi Manish, Doc vK here. I love your article, but have one question. In the Python for PC analysis you used a clean data, where missing values have been imputed, and categorical variables are converted into numeric. Does Python contain libraries similar to the ones used in r? Fie example/ what would be the Python code similar to the r library "Dummies"? ... I would appreciate seeing the Python code similar to the r code. Thanks!

Nice Post, When will you publish the post on Factor Analysis?

Hi, Thanks for this article. I have a question. I have 50 observations (10x5groups) of 231 variables and I'd like to use PCA with R in order to select the best variables. The problem is that "prcomp(mydata)" yields 50 components. Thus, if I understood, it will allow me remove some observations... but I need to select variables to model all my observations.

In the part where you use R, in the last paragraph of number 3, I don't understand how we can infer from the figure what the first and second principal components correspond to. I would appreciate any explanation. Thank you.

Article is very informative.Thank you Manish.

Hi Manish, A great article. I have few questions. 1 How do we find features that contribute for PC1 to PC30? 2 Do you have the article for modelling stage? 3 How do we validate the model in PCA? Thanks

Hi Norman 1. You can decide on PC1 to PC30 by looking at the cumulative variance bar plot. Basically, this plot says how many component combined can explain variance in the data. If you see carefully, after PC30, the line saturates and adding any further component doesn't help in more explained variance. 2. Just added today. 3. For validation, divide the training set into n parts. Run PCA on one part. Then, apply this resultant PCA on other parts and finally make predictions (as explained above)

Hi I refer to your statement : If the two components are uncorrelated, their directions should be orthogonal (image below). Can I said that : To be a "valid" predictors, does it mean there must be NO co-relational directional arrow pointing ? In another words, the independent predictors must NOT arrow in the same direction ? What if 2 components arrow in a pictures goes in the same directions ?

biplot(prin_comp, scale = 0) The black smudges on the graphics - is it a indication that these are the predictors that contribute to the data variance ?

Regards from Colombia. Great tutorial!!! Very well explained. Congratulations

Hi I have one doubt. After Predicting the Item_Outlet_Sales if i want to know which Original Predictors contributes most towards the target variable how i can find this ?? Because now all the predictors are converted into principal components . Please tell me a way to find out the relative importance of all predictor variable after reducing dthe dimension of data using PCA.

Hi Sanchit See biplot, it would help you to figure out which variables contribute to which component.

Hi Manish I applied linear reg on same dataset big mart sales with PCs as ind variables. However my r2 reduced drastically compare to reg using original ind variables. Any idea what went wrong. Regards Mithilesh

Hi Mithilesh PCA works best when we've several numeric features. In this data set, since majority of the variables are categorical, I converted those categorical variables into numeric using one hot encoding. For a linear regression, this approach doesn't work since encoded variables might add to non-linearity in the data. Therefore, your regression model on PCA components is giving poor results. To summarize, PCA also has limitations. It wouldn't work well in all situations. If you really want to leverage its power, download data from numer.ai website, you'll enjoy it.

Hi Manish, Many thanks for this detailed work on PCA. Greetings from Nigeria

Hi! I always enjoy your articles. Got a query. In the statement "In general, for n Ã— p dimensional data, min(n-1, p) principal component can be constructed." Do u mean Maximum here? If not can you please explain why it is min(n-1,p)?

Beautifully Explained Manish. Really liked the part where you clarified on how to do it on test data,

Superb manish. what a command (over both statistics and R!).

Excellent . This is at par with some of the best online courses of US universities. Very well explained in the most simple way. Waiting for your article in feature selection in R and once again Xgboost.

kindly tell me how to find out the percentage of variance expreienced by each principal component?any command.i m using R for my analysis

Absolutely. In a data set, the maximum number of principal component loadings is a minimum of (n-1, p). Why is this?

nice article Manish. :)

Hey, the variable "Item_Fat_Content" has different levels but I think 3 of them are just the same: LF, low fat & Low Fat.. The table that is posted in the article (post this command: prin_comp$rotation[1:5,1:4] ) has all 3 of them too against the principal components. So my doubt is , don't we need to club all those categories in to one? Sorry, v silly question but really new to PCA so thought should clear it out. Another question: I wanted to have a look at the correlation matrix but the cor(dataframe, method="") approach doesn't give a good graph (could be because of factor variables or due to high dimensionality of the data frame). So, what can I do to see the correlation graph/numbers or just plotting the principal components is enough? Will be glad to receive any help on this. Thanks

Wanted to understand why you have calculated the std deviation and variances as these are already provided by summary(prin_comp). Similarily why did you write separate code for plotting the screeplot, when again you could have used plot(prin_comp, type="lines") or the screeplot() function

This is excellent explanations!!! Thank you so much for your help!

considering above example, I would like to know the what is PC1( principal component 1) i.e ., it is a linear combination of few independent variables . i wanted to know what is that equation in R software.

Dear Manish, Thank you for your comprehensive article on PCA. I really enjoy reading it. I am using Matlab and I am trying to picture my problem in the way that you explained PCA in your article. I would appreciate if you could guide me on this. I have a dataset of 2643 (n) x 8(p). I have a Matlab code that could generate 1D PCA for 2D inputs: (e.g. p1 and p2). Given that I have total 8p I can generate 28 1D PCA for different combinations e.g.: p1xp2, p1xp3,., p1xp4,....p7xp8. My question is: is it correct to generate 28 plots for 8 p and then calculate the PC score vector? Regards, Ngh

We infer than first principal component corresponds to a measure of Outlet_TypeSupermarket, Outlet_Establishment_Year 2007. Similarly, it can be said that the second component corresponds to a measure of Outlet_Location_TypeTier1, Outlet_Sizeother. Can you please further elaborate how did you deduce this ?? regards Abhijeet

Very well written Manish. I could easily follow each steps and apply PCA on my work.

import numpy as np from sklearn.decomposition import PCA import pandas as pd import matplotlib.pyplot as plt from sklearn.preprocessing import scale %matplotlib inline #Load data set data = pd.read_csv('Big_Mart_PCA.csv') #convert it to numpy arrays X=data.values #Scaling the values X = scale(X) pca = PCA(n_components=44) pca.fit(X) after executing this i am getting the below error ValueError: could not convert string to float: Supermarket Type1 i tried resolving it using the below commmand data['Outlet_Type'] = pd.to_numeric(data['Outlet_Type'], errors='coerce') but again its giving me the same error

Hi Team, Thanks a lot for a very comprehensive description of each and every item of the PCA. However, one thing is still not very clear to me. Let's consider a regression context. After PCs are obtained, now they are predictors for my regression and consequently I'll get betas/coefficients for each PC. But client is interested in quantifying the impact of each individual variable, not of individual PC, that is to know how much each variable is attributing the response or betas of individual variable. Now the question is since each PC contains all the predictor variables, how to obtain betas for individual variable. Please let me know. It would be of great help. Thank you.

Hi, really enjoyed and got an insight into pca through this post ... I had a doubt like once you have selected the important components how can the data in terms of original i mean un normalized can be obtained using selected components

Hi, I applied PCA on a data-set where I was to predict the chance of a person having lung cancer. In the model that I am able to make, I got AIC = 940. This was when I was considering 30 PCs (accounting for 94% of the variance in the data) When I removed all but 10 of the variables (shown to be significant by its p-value ) and ran the log-regression again. The AIC came down to 894 but no lower. I know it is still too high, can you suggest some techniques to improve the model's fit? Thanks in advance and love this website.

As a beginner to data analytics, I have been trying to grasp PCA method in the past couple of weeks. Really well explained, with theory, application and pitfalls, Subscribed. Thanks!

While looking at the str(new_mydata) after one hot encoding, I am getting only one level of the variable "Outlet_Establishment_Year". I can alse see various levels of "Outlet_Establishment_Year" in the biplot as well. Also, it has been mentioned that 6 out of 9 variables are categorical in nature. Does that include "Outlet_Establishment_Year" as well ? "Outlet_Establishment_Year" is integer in nature as can be seen in str(my_data). Can someone explain

Hi Manish, Thanks for the great article. I have a question about applying the modeling part in Python. How do we apply on test PCA and scaling on test data?

Thank you for the information you shared. but I want to ask a question. I have a 5000x21 data set. When I apply pca to the dataset as shown, I get the following result: var1 = [100. 100, 100, 100, 100, 100, 100, 100, 100, 100, 100, 100, 100, 100. 100. 100. 100. 100. 100. 100. 100.] According to this result, what value should I assign to the variable n_components? please help me. Thank you

Hii.. I'm doing a project work for my presentation and I want to know that how to reduce data set in bank loan requirements using PCA , and how this will be done mathematically . And how to create the data set for this...plz reply . Because I have to submit my work on this as soon as possible

It was great. Thanks a lot

Hi- I think this article is showing the wrong Table of Contents. Thanks!

i want to apply pca using covariance and corellation in python