In this challenge, you'll build and train a **variational autoencoder (VAE)** on the MNIST dataset — step by step. You'll define the architecture, implement the reparameterization trick, create the custom loss, and run the full training process.

To make your experience smoother, you can choose one of the following options to work with the code:

* <a href="https://staging-content-media-cdn.codefinity.com/37287944-3858-4d25-b5b4-8963c453781b/mnist_vae_notebook.ipynb" target="_blank"><svg width="1em" height="1em" viewBox="0 0 30 32" fill="none" xmlns="http://www.w3.org/2000/svg"><path fill="none" stroke="#098f67" style="stroke: var(--color1, #098f67)" stroke-linejoin="miter" stroke-linecap="round" stroke-miterlimit="4" stroke-width="2.4156" d="M17.289 17.305v0c-1.754 1.754-4.597 1.754-6.351 0l-7.76-7.759c-1.755-1.755-1.755-4.601 0-6.356v0c1.753-1.753 4.595-1.756 6.351-0.005l6.208 6.187"></path><path fill="none" stroke="#098f67" style="stroke: var(--color1, #098f67)" stroke-linejoin="miter" stroke-linecap="round" stroke-miterlimit="4" stroke-width="2.4156" d="M12.504 13.97v0c1.754-1.754 4.597-1.754 6.351 0l7.762 7.762c1.754 1.754 1.754 4.597 0 6.351v0c-1.754 1.754-4.597 1.754-6.351 0l-5.953-5.953"></path></svg> Download the notebook</a> and run it locally in your favorite environment (e.g., VSCode, Jupyter, PyCharm);
* <a href="https://drive.google.com/file/d/1AQiu8DIV5inr1A4K6W8-KcVC8T1Cr-kG/view?usp=sharing" target="_blank"><svg width="1em" height="1em" viewBox="0 0 30 32" fill="none" xmlns="http://www.w3.org/2000/svg"><path fill="none" stroke="#098f67" style="stroke: var(--color1, #098f67)" stroke-linejoin="miter" stroke-linecap="round" stroke-miterlimit="4" stroke-width="2.4156" d="M17.289 17.305v0c-1.754 1.754-4.597 1.754-6.351 0l-7.76-7.759c-1.755-1.755-1.755-4.601 0-6.356v0c1.753-1.753 4.595-1.756 6.351-0.005l6.208 6.187"></path><path fill="none" stroke="#098f67" style="stroke: var(--color1, #098f67)" stroke-linejoin="miter" stroke-linecap="round" stroke-miterlimit="4" stroke-width="2.4156" d="M12.504 13.97v0c1.754-1.754 4.597-1.754 6.351 0l7.762 7.762c1.754 1.754 1.754 4.597 0 6.351v0c-1.754 1.754-4.597 1.754-6.351 0l-5.953-5.953"></path></svg> <b>Open in Google Colab</b></a> - just one click and everything is ready to run online.

Once you open the notebook, you'll see a series of tasks.
Each task includes:

* Clear instructions;
* Code with blanks to fill in;
* Checkers that verify your solution.

When your implementation is correct, the checker will display a short key.
Collect **all the keys** from every step — you'll need them at the end.

This course provides a comprehensive introduction to Generative AI, covering its theoretical foundations, practical applications, and ethical considerations. Learners will explore various generative models, their training methods, and real-world use cases while also addressing the challenges and risks associated with AI-generated content.

This section introduces the core concepts of Generative AI, explaining how it differs from traditional AI and its significance in modern technology. Learners will explore the history of generative models, from early rule-based systems to advanced deep learning architectures like GANs and Transformers. By the end of this section, students will have a clear understanding of the key models and their real-world impact.

This section delves into the mathematical and computational principles that power Generative AI. Topics include probability distributions, Bayesian inference, and neural networks, which form the backbone of generative models. Students will gain insight into how deep learning techniques enable AI systems to create realistic text, images, and other forms of synthetic data.

In this section, students will learn how generative models are trained, optimized, and evaluated. Key topics include data collection, preprocessing techniques, loss functions, and performance metrics used to assess AI-generated content. Hands-on insights into training models like GANs and VAEs will help learners understand the practical challenges and trade-offs in model development.

This section explores key challenges in Generative AI, including ethical concerns, legal issues, and environmental impact. It also highlights emerging regulations and future trends shaping responsible AI development.

Challenge: Build Simple VAE

Awesome!

Challenge: Build Simple VAE