Advanced Machine Learning Techniques

This course is part of Machine Learning with Scikit-learn, PyTorch & Hugging Face Professional Certificate

Instructor: Professionals from the Industry

Access provided by Datta Meghe Institute of Higher Education & Research (DU)

5 modules

Gain insight into a topic and learn the fundamentals.

Intermediate level

Recommended experience

3 weeks to complete

at 10 hours a week

Flexible schedule

Learn at your own pace

5 modules

Gain insight into a topic and learn the fundamentals.

Intermediate level

Recommended experience

3 weeks to complete

at 10 hours a week

Flexible schedule

Learn at your own pace

Skills you'll gain

Data Processing

Details to know

Shareable certificate

Add to your LinkedIn profile

Assessments

22 assignments

Taught in English

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This course is part of the Machine Learning with Scikit-learn, PyTorch & Hugging Face Professional Certificate

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There are 5 modules in this course

Welcome to Advanced Machine Learning Techniques, where you'll dive deep into sophisticated approaches that power modern AI applications. We'll explore five key areas of advanced ML: ensemble methods for combining models, dimensionality reduction techniques for handling complex data, natural language processing for text analysis, reinforcement learning for decision-making systems, and automated machine learning for optimization. You'll work hands-on with industry-standard tools including Scikit-learn, XGBoost, NLTK, PyTorch, and MLflow, learning how to implement and optimize advanced algorithms in real-world scenarios.

By the end of this course, you'll be able to: -Implement ensemble methods including bagging, boosting, and stacking to enhance model performance -Apply dimensionality reduction techniques like PCA, t-SNE, and UMAP for data visualization and feature extraction -Process and analyze text data using modern NLP techniques and transformer models -Design and train reinforcement learning agents for autonomous decision-making -Optimize machine learning workflows using AutoML tools and experiment tracking Through practical exercises and a comprehensive capstone project, you'll develop the advanced skills needed to tackle complex machine learning challenges in your professional work.

In this module, you will establish ensemble learning techniques including bagging, boosting, and stacking. You'll learn how to combine multiple models to improve predictive performance and implement them using popular libraries like Scikit-learn, XGBoost, and LightGBM. Through hands-on practice, you'll evaluate ensemble models using cross-validation and learn to optimize their hyperparameters.

What's included

16 videos8 readings5 assignments4 ungraded labs4 plugins

16 videosTotal 47 minutes

Welcome to Advanced Machine Learning Techniques2 minutes
Why Single Decision Trees Can Overfit: A Visual Primer2 minutes
How Bagging Stabilizes Predictions and Reduces Variance2 minutes
Random Forest for Classification: Iris Dataset Walkthrough3 minutes
Random Forest for Regression: Predicting House Prices2 minutes
Why Weak Learners Fail — And What Boosting Tries to Fix1 minute
How Boosting Learns from Mistakes — One Model at a Time3 minutes
Implementing XGBoost and LightGBM for Boosted Classification2 minutes
What Is Stacking? A Simple Visual Explanation3 minutes
How to Train a Stacking Model (Without Leaking Data)3 minutes
Hands-On: Setting Up Base Models for Stacking in Scikit-learn4 minutes
Hands-On: Training and Evaluating a Stacked Ensemble in Python2 minutes
Cross-Validation Basics: How It Works, Why It Matters, and Why a Single Data Split Can Mislead You3 minutes
How Cross-Validation Makes Model Comparison More Reliable3 minutes
Cross-Validation with cross_val_score: Comparing Ensemble Models2 minutes
Hyperparameter Tuning with GridSearchCV: Optimizing XGBoost3 minutes

8 readingsTotal 74 minutes

Understanding Bagging and Random Forests 8 minutes
Understanding Hyperparameters in Random Forests10 minutes
Boosting Algorithms Explained: From AdaBoost to XGBoost & LightGBM10 minutes
Tuning Boosting Models: Key Hyperparameters Explained10 minutes
When and How to Use Stacking Effectively8 minutes
Stacking in Practice: Understanding the StackingClassifier Structure8 minutes
Implementing Cross-Validation10 minutes
Cross-Validation and the Bias-Variance Trade-Off in Ensemble Models10 minutes

5 assignmentsTotal 90 minutes

Ensemble Learning Mastery30 minutes
Knowledge Check: Bagging and Random Forests15 minutes
Knowledge Check: Boosting and Its Applications15 minutes
Knowledge Check: StackingClassifier in Action15 minutes
Knowledge Check: Model Evaluation for Ensembles15 minutes

4 ungraded labsTotal 240 minutes

Bagging in Action: Predicting Customer Churn with Random Forest60 minutes
Using Boosting Models to Predict Heart Disease60 minutes
Building and Evaluating a StackingClassifier on Loan Default Data60 minutes
Comparing Ensemble Models with Cross-Validation60 minutes

4 pluginsTotal 28 minutes

When Is Bagging the Right Choice?7 minutes
Should You Always Use Boosting Over Bagging?7 minutes
How Do You Choose the Right Base and Meta Models for Stacking?7 minutes
Understanding Bias-Variance Trade-offs in Ensemble Models7 minutes

This module will help you master dimensionality reduction techniques to handle high-dimensional data effectively. You'll learn to apply Principal Component Analysis (PCA) to reduce dimensionality while retaining key features, use t-distributed Stochastic Neighbor Embedding (t-SNE) to visualize high-dimensional data in 2D/3D space for clustering and pattern recognition, and implement Uniform Manifold Approximation and Projection (UMAP) for efficient dimensionality reduction, leveraging its speed and structure-preserving properties.

What's included

8 videos7 readings4 assignments3 ungraded labs1 plugin

8 videosTotal 15 minutes

Why Reducing Dimensions Makes Your Models Work Better2 minutes
Implementing PCA Step-by-Step in Python2 minutes
How PCA Reduces Dimensions and Visualizes Patterns1 minute
Why PCA Isn't Always Enough: Enter t-SNE1 minute
Hands-On with t-SNE: Visualizing Complex Patterns in 2D1 minute
Why UMAP Is a Game-Changer for Visualizing and Modeling Complex Data1 minute
Visualizing Digits with UMAP in Python2 minutes
Using UMAP-Transformed Features for Classification2 minutes

7 readingsTotal 52 minutes

Why We Use PCA: Dimensionality Reduction & Variance8 minutes
How PCA Works: Eigenvectors, Projection & Explained Variance8 minutes
What Is t-SNE and How Is It Different from PCA?6 minutes
How to Use t-SNE Effectively: Parameters, Best Practices, and Pitfalls6 minutes
Visualizing High-Dimensional Data: Why PCA and t-SNE Aren't Always Enough6 minutes
UMAP Demystified: What It Is—and What It Isn't8 minutes
Using UMAP Effectively: Parameters, Use Cases, and Cautions10 minutes

4 assignmentsTotal 75 minutes

Dimensionality Reduction Mastery30 minutes
Knowledge Check: Principal Component Analysis (PCA)15 minutes
Knowledge Check: t-SNE Concepts & Use Cases15 minutes
Knowledge Check: UMAP Essentials15 minutes

3 ungraded labsTotal 180 minutes

Reducing Dimensionality with PCA: From 64 Features to 260 minutes
Visualizing Handwritten Digit Clusters with t-SNE60 minutes
Exploring UMAP for Visualization and Modeling60 minutes

1 pluginTotal 7 minutes

UMAP, t-SNE, or PCA: Which One Should You Choose?7 minutes

In this module, you'll focus on natural language processing techniques from basic text preprocessing to advanced sentiment analysis. You'll learn how to preprocess text data using tokenization, stopword removal, and stemming/lemmatization with Natural Language Toolkit (NLTK) and spaCy. Through implementation of text classification using various techniques like Bag-of-Words, TF-IDF, and word embeddings, you'll gain practical experience in NLP tasks. You'll also train sentiment analysis models using Hugging Face Transformers and Scikit-learn.

What's included

13 videos6 readings5 assignments4 ungraded labs2 plugins

13 videosTotal 26 minutes

Understanding Natural Language Processing: Why It Matters Today1 minute
Cleaning Raw Text Step by Step – From Noise to Tokens2 minutes
Stemming vs. Lemmatization – What's the Difference?1 minute
From Text to Bag-of-Words – Your First Text Vectorizer1 minute
Going Beyond Counts – TF-IDF in Action1 minute
Extracting Token Embeddings with Hugging Face Transformers2 minutes
Sentence-Level Embeddings and Similarity Scoring2 minutes
How Tokenization Works: Words, Subwords, and Transformers2 minutes
Getting Word Vectors and Token Similarity with spaCy2 minutes
Creating Sentence Embeddings with Hugging Face Transformers1 minute
TF-IDF Vectorization for Sentiment Data2 minutes
Training and Evaluating a Sentiment Classifier1 minute
Fine-Tuning BERT for Sentiment Analysis with Hugging Face Transformers2 minutes

6 readingsTotal 47 minutes

Why Preprocessing Text Is the First Step to Better Models8 minutes
Stemming, Lemmatization, and Tools to Preprocess8 minutes
From Words to Counts – Understanding BoW and TF-IDF8 minutes
From Vectors to Meaning – Embeddings and When to Use Them6 minutes
Tokenizers and Embeddings: How Modern NLP Models Understand Language10 minutes
Text Classification: From Features to Predictions7 minutes

5 assignmentsTotal 90 minutes

NLP Mastery – From Text to Classification30 minutes
Knowledge Check: Text Preprocessing Techniques15 minutes
Knowledge Check: Word Representations15 minutes
Knowledge Check: Tokenization & Embeddings 15 minutes
Knowledge Check: Sentiment Classification Workflows15 minutes

4 ungraded labsTotal 240 minutes

Clean Your First NLP Dataset: News Headlines Edition60 minutes
Comparing Sparse and Dense Text Representations in Practice60 minutes
Compare Static vs. Contextual Embeddings for Sentence Similarity60 minutes
Classical vs. Transformer Sentiment Models: A Head-to-Head Comparison60 minutes

2 pluginsTotal 14 minutes

How Do You Choose the Right Word Representation?7 minutes
When Should You Choose Classical ML vs. Transformers7 minutes

Reinforcement Learning Description: In this module, you'll explore the fundamentals of reinforcement learning (RL), including Markov Decision Processes (MDPs) and reward-based learning. You'll understand the key components of RL systems and implement both policy-based and value-based learning techniques. Through practical examples and hands-on implementation, you'll discover how RL is applied in real-world scenarios like robotics, gaming, and finance.

What's included

7 videos5 readings4 assignments3 ungraded labs1 plugin

7 videosTotal 16 minutes

What Makes Reinforcement Learning Different1 minute
Getting Started with Reinforcement Learning: Agents, Actions, and Rewards3 minutes
Simulating a Reinforcement Learning Loop in Python2 minutes
Understanding Q-Learning and the Bellman Update2 minutes
Implementing Q-Learning in GridWorld2 minutes
Building a Policy Network and Sampling Actions1 minute
Training with the REINFORCE Algorithm3 minutes

5 readingsTotal 40 minutes

Key Concepts of Reinforcement Learning8 minutes
The Markov Decision Process and RL Terminology8 minutes
Value vs Policy: Two Ways to Train an RL Agent10 minutes
How RL Powers Robots, Games, and Financial Decisions6 minutes
Challenges and Frontiers of Real-World RL8 minutes

4 assignmentsTotal 75 minutes

Reinforcement Learning Mastery30 minutes
Knowledge Check: RL Fundamentals15 minutes
Knowledge Check: Q-Learning vs. REINFORCE15 minutes
Knowledge Check: RL in the Real World15 minutes

3 ungraded labsTotal 180 minutes

Simulate Your First RL Environment with an Agent in GridWorld60 minutes
Train Your First Q-Learning and REINFORCE Agents60 minutes
Simulating a Real-World Decision Task Using RL Concepts60 minutes

1 pluginTotal 1 minute

Should You Really Use RL for This Problem?1 minute

This module focuses on automated machine learning techniques and model optimization. You'll learn to automate model selection and hyperparameter tuning using Auto-sklearn and GridSearchCV, and optimize models using MLflow for experiment tracking and reproducibility. You'll also explore Bayesian optimization techniques to improve model accuracy. The module concludes with a comprehensive capstone project that combines multiple techniques from throughout the course.