# Deep Learning: Recurrent Neural Networks in Python

**GRU, LSTM, + more modern deep learning, machine learning, and data science for sequences**

**What Will I Learn?**

- Understand the simple recurrent unit (Elman unit)
- Understand the GRU (gated recurrent unit)
- Understand the LSTM (long short-term memory unit)
- Write various recurrent networks in Theano
- Understand backpropagation through time
- Understand how to mitigate the vanishing gradient problem
- Solve the XOR and parity problems using a recurrent neural network
- Use recurrent neural networks for language modeling
- Use RNNs for generating text, like poetry
- Visualize word embeddings and look for patterns in word vector representations

**Requirements**

- Calculus
- Linear algebra
- Python, Numpy, Matplotlib
- Write a neural network in Theano
- Understand backpropagation
- Probability (conditional and joint distributions)
- Write a neural network in Tensorflow

**Description**

Like the course I just released on **Hidden Markov Models**, **Recurrent Neural Networks** are all about learning sequences – but whereas Markov Models are limited by the Markov assumption, Recurrent Neural Networks are not – and as a result, they are more expressive, and more powerful than anything we’ve seen on tasks that we haven’t made progress on in decades.

So what’s going to be in this course and how will it build on the previous neural network courses and Hidden Markov Models?

In the first section of the course we are going to add the concept of **time** to our neural networks.

I’ll introduce you to the **Simple Recurrent Unit**, also known as the **Elman unit**.

We are going to revisit the XOR problem, but we’re going to extend it so that it becomes the parity problem – you’ll see that regular **feedforward neural networks** will have trouble solving this problem but recurrent networks will work because the key is to treat the input as a sequence.

In the next section of the course, we are going to revisit one of the most popular applications of recurrent neural networks – **language modeling**.

You saw when we studied Markov Models that we could do things like generate poetry and it didn’t look too bad. We could even discriminate between 2 different poets just from the sequence of parts-of-speech tags they used.

In this course, we are going to extend our language model so that it no longer makes the Markov assumption.

Another popular application of neural networks for language is **word vectors** or **word embeddings**. The most common technique for this is called **Word2Vec**, but I’ll show you how recurrent neural networks can also be used for creating word vectors.

In the section after, we’ll look at the very popular **LSTM**, or **long short-term memory unit**, and the more modern and efficient **GRU**, or **gated recurrent unit**, which has been proven to yield comparable performance.

We’ll apply these to some more practical problems, such as learning a language model from **Wikipedia data** and visualizing the word embeddings we get as a result.

All of the materials required for this course can be downloaded and installed for FREE. We will do most of our work in **Numpy,** **Matplotlib**, and **Theano**. I am always available to answer your questions and help you along your data science journey.

This course focuses on “**how to build and understand**“, not just “how to use”. Anyone can learn to use an API in 15 minutes after reading some documentation. It’s not about “remembering facts”, it’s about **“seeing for yourself” via experimentation**. It will teach you how to visualize what’s happening in the model internally. If you want **more** than just a superficial look at machine learning models, this course is for you.

See you in class!

**NOTES:**

All the code for this course can be downloaded from my github: /lazyprogrammer/machine_learning_examples

In the directory: rnn_class

Make sure you always “git pull” so you have the latest version!

**HARD PREREQUISITES / KNOWLEDGE YOU ARE ASSUMED TO HAVE:**

- calculus
- linear algebra
- probability (conditional and joint distributions)
- Python coding: if/else, loops, lists, dicts, sets
- Numpy coding: matrix and vector operations, loading a CSV file
- Deep learning: backpropagation, XOR problem
- Can write a neural network in Theano and Tensorflow

**TIPS (for getting through the course):**

- Watch it at 2x.
- Take handwritten notes. This will drastically increase your ability to retain the information.
- Write down the equations. If you don’t, I guarantee it will just look like gibberish.
- Ask lots of questions on the discussion board. The more the better!
- Realize that most exercises will take you days or weeks to complete.
- Write code yourself, don’t just sit there and look at my code.

**USEFUL COURSE ORDERING:**

- (The Numpy Stack in Python)
- Linear Regression in Python
- Logistic Regression in Python
- (Supervised Machine Learning in Python)
- (Bayesian Machine Learning in Python: A/B Testing)
- Deep Learning in Python
- Practical Deep Learning in Theano and TensorFlow
- (Supervised Machine Learning in Python 2: Ensemble Methods)
- Convolutional Neural Networks in Python
- (Easy NLP)
- (Cluster Analysis and Unsupervised Machine Learning)
- Unsupervised Deep Learning
- (Hidden Markov Models)
- Recurrent Neural Networks in Python
- Artificial Intelligence: Reinforcement Learning in Python
- Natural Language Processing with Deep Learning in Python

**Who is the target audience?**

- If you want to level up with deep learning, take this course.
- If you are a student or professional who wants to apply deep learning to time series or sequence data, take this course.
- If you want to learn about word embeddings and language modeling, take this course.
- If you want to improve the performance you got with Hidden Markov Models, take this course.
- If you’re interested the techniques that led to new developments in machine translation, take this course.
- If you have no idea about deep learning, don’t take this course, take the prerequisites.

**Size: 629.16 MB**

**https://www.udemy.com/deep-learning-recurrent-neural-networks-in-python/.**