Mastering Generative AI: A Roadmap from Zero to Expertise in Gen AI field



Are you interested in learning Generative AI but worried about the math involved? Don’t fret! In this guide, we’ll break down the syllabus and the best ways to learn Generative AI, even if you’re from a different field or department. We’ll make complex concepts easy to understand, so you can embark on your Generative AI journey with confidence.

Important of Generative AI

The global artificial intelligence (AI) market size was valued at USD 454.12 billion in 2022 and is expected to hit around USD 2,575.16 billion by 2032, progressing with a compound annual growth rate (CAGR) of 19% from 2023 to 2032.

According to PwC, AI is set to create 15.7 million new jobs in the UK by 2037 while displacing 7 million. This results in a net gain of 8.7 million jobs, around 22% of the current workforce. These new jobs will focus on human skills like creativity, empathy, and problem-solving, particularly in sectors like education, healthcare, and social services.

Now, let’s dive into a detailed breakdown of the syllabus.

1. Mathematics for Machine Learning

Before mastering machine learning, it is important to understand the fundamental mathematical concepts that power these algorithms.

  • Linear Algebra: This is crucial for understanding many algorithms, especially those used in deep learning. Key concepts include vectors, matrices, determinants, eigenvalues and eigenvectors, vector spaces, and linear transformations.
  • Calculus: Many machine learning algorithms involve the optimization of continuous functions, which requires an understanding of derivatives, integrals, limits, and series. Multivariable calculus and the concept of gradients are also important.
  • Probability and Statistics: These are crucial for understanding how models learn from data and make predictions. Key concepts include probability theory, random variables, probability distributions, expectations, variance, covariance, correlation, hypothesis testing, confidence intervals, maximum likelihood estimation, and Bayesian inference.

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2. Python for Machine Learning

Python is a powerful and flexible programming language that’s particularly good for machine learning, thanks to its readability, consistency, and robust ecosystem of data science libraries.

  • Python Basics: Understanding of Python’s basic syntax, data types, error handling, and object-oriented programming is crucial.
  • Data Science Libraries: Familiarity with NumPy for numerical operations, Pandas for data manipulation and analysis, Matplotlib and Seaborn for data visualization is a must.
  • Data Pre-processing: This involves feature scaling and normalization, handling missing data, outlier detection, categorical data encoding, and splitting data into training, validation, and test sets.
  • Machine Learning Libraries: Proficiency with Scikit-learn, a library providing a wide selection of supervised and unsupervised learning algorithms, is vital. Understanding how to implement algorithms like linear regression, logistic regression, decision trees, random forests, k-nearest neighbors (K-NN), and K-means clustering is important. Dimensionality reduction techniques like PCA and t-SNE are also very helpful for visualizing high-dimensional data.

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3. Neural Networks

Neural networks are a fundamental part of many machine learning models, particularly in the realm of deep learning. To utilize them effectively, a comprehensive understanding of their design and mechanics is essential.

  • Fundamentals: This includes understanding the structure of a neural network such as layers, weights, biases, activation functions (sigmoid, tanh, ReLU, etc.)
  • Training and Optimization: Familiarize yourself with backpropagation and different types of loss functions, like Mean Squared Error (MSE) and Cross-Entropy. Understand various optimization algorithms like Gradient Descent, Stochastic Gradient Descent, RMSprop, and Adam.
  • Overfitting: It’s crucial to comprehend the concept of overfitting (where a model performs well on training data but poorly on unseen data) and various regularization techniques to prevent it. Techniques include dropout, L1/L2 regularization, early stopping, and data augmentation.
  • Implement a Multilayer Perceptron (MLP): Build an MLP, also known as a fully connected network, using PyTorch.

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4. Natural Language Processing (NLP)

NLP is a fascinating branch of artificial intelligence that bridges the gap between human language and machine understanding. From simple text processing to understanding linguistic nuances, NLP plays a crucial role in many applications like translation, sentiment analysis, chatbots, and much more.

  • Text Preprocessing: Learn various text preprocessing steps like tokenization (splitting text into words or sentences), stemming (reducing words to their root form), lemmatization (similar to stemming but considers the context), stop word removal, etc.
  • Feature Extraction Techniques: Become familiar with techniques to convert text data into a format that can be understood by machine learning algorithms. Key methods include Bag-of-words (BoW), Term Frequency-Inverse Document Frequency (TF-IDF), and n-grams.
  • Word Embeddings: Word embeddings are a type of word representation that allows words with similar meanings to have similar representations. Key methods include Word2Vec, GloVe, and FastText.
  • Recurrent Neural Networks (RNNs): Understand the working of RNNs, a type of neural network designed to work with sequence data. Explore LSTMs and GRUs, two RNN variants that are capable of learning long-term dependencies.

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5. The Transformer Architecture

The Transformer model, introduced in the “Attention is All You Need” paper, is the neural network architecture at the core of large language models. The original paper is difficult to read and eveb contains some mistakes, which is why alternative resources are recommended.

  • Attention Mechanisms: Grasp the theory behind attention mechanisms, including self-attention and scaled dot-product attention, which allows the model to focus on different parts of the input when producing an output.
  • Tokenization: Understand how to convert raw text data into a format that the model can understand, which involves splitting the text into tokens (usually words or subwords).
  • Transformer Architecture: Dive deeper into the architecture of Transformers, learning about their various components such as positional encoding, multi-head attention, feed-forward networks, and normalization layers.
  • Decoding Strategies: Learn about the different ways the model can generate output sequences. Common strategies include greedy decoding, beam search, and top-k sampling.

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6. Pre-trained Language Models

Pre-trained models like BERT, GPT-2, and T5 are powerful tools that can handle tasks like sequence classification, text generation, text summarization, and question answering.

  • BERT: Understand BERT’s architecture, including the concept of bidirectional training, which distinguishes it from previous models. Learn about fine-tuning BERT for tasks like sequence classification, named entity recognition, and question answering.
  • GPT-2: Understand GPT-2’s decoder-only architecture and its pre-training objective. Learn to use it for text generation.
  • T5: the T5 model is a highly versatile model for tasks ranging from text classification to translation to summarization. Understand how to train and use T5 for multiple tasks, and learn about the “prefix-tuning” approach used with T5.
  • LLM Evaluation: Learn how to evaluate the performance of these models on your specific task, including appropriate metrics for different tasks such as accuracy, F1 score, BLEU score, or perplexity.

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7. Advanced Language Modeling

To fine-tune your skills, learn how to create embeddings with sentence transformers, store them in a vector database, and use parameter-efficient supervised learning or RLHF to fine-tune LLMs.

  • Sentence Transformers: Sentence Transformers are models that can derive semantically meaningful embeddings for sentences, paragraphs, or texts. Learn how to store and retrieve these embeddings using an appropriate vector database for rapid similarity search.
  • Fine-Tuning Language Models: After understanding and using pre-trained models, the next step is fine-tuning them on a domain-specific dataset. It allows the model to be more accurate for certain tasks or domains, such as medical text analysis or sentiment analysis for movie reviews.
  • Parameter-Efficient Learning Techniques: Explore more efficient ways to train or fine-tune your models without requiring massive amounts of data or computational resources, such as LoRA.

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8. LLMOps

Finally, dive into Large Language Model Operations (LLMOps), learn how to handle prompt engineering, build frameworks with LangChain and Llamaindex, and optimize inference with weight quantization, pruning, distillation, and more.

  • Fine-tuning LLaMA: Instruction fine-tuning has become extremely popular since the (accidental) release of LLaMA. The size of these models and the peculiarities of training them on instructions and answers introduce more complexity and often require parameter-efficient learning techniques such as QLoRA.
  • Build LLM Frameworks: LLMs are a new building block in system design, where the rest of the architecture is handled by libraries such as LangChain and LlamaIndex, allowing you to query vector databases, improving the model’s memory or providing various tools.
  • Optimization Techniques for Inference: As the size of LLMs grows, it becomes increasingly important to apply optimization techniques to ensure that the models can be efficiently used for inference. Techniques include weight quantization (4-bit, 3-bit), pruning, knowledge distillation, etc.
  • LLM deployment: These models can be deployed locally like llama.cpp or in the cloud like Hugging Face’s text generation inference or vLLM.

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In closing, I’ve outlined the roadmap to understanding the intricate world of Generative AI and LLM (Language Model Learning). We’ve delved into the core concepts, real-world applications, and the ever-evolving landscape of this cutting-edge field.

Internship Opportunity

But here’s the exciting part: we’re not stopping here. At Gathnex, we’re always looking to nurture the next generation of AI enthusiasts and professionals. That’s why we’re thrilled to announce our upcoming Generative AI Internship program.

We are actively planning and preparing to launch this internship initiative, where you can gain hands-on experience, work on cutting-edge projects, and learn from experts in the field. Whether you’re a student, recent graduate, or someone looking to pivot into the world of AI, our internship program will offer a valuable opportunity to grow and contribute to the field.

So, if you’re as passionate about AI as we are and want to be part of our journey, stay tuned for updates. Follow us, bookmark our website, and keep an eye out for further announcements. The future of Generative AI is bright, and we want you to be a part of it.

Thank you for being a vital part of our community, and we can’t wait to embark on this exciting internship journey with you!

Source :

  1. https://roadmap.sh/guides/introduction-to-llms
  2. https://roadmap.sh/guides/free-resources-to-learn-llms
  3. https://github.com/mlabonne/llm-course
  4. https://github.com/gokulrajar15/nlp-tutorial/tree/master
  5. https://skillmapper.com/home/collections/466/LLM-Learning-Roadmap-From-Beginner-to-Advanced-

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