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How to build RNNs and LSTMs from scratch with NumPy

[Update 08/18/2020] Improvements to dataset; exercises and descriptions have been made more clear.

Originally developed by me (Nicklas Hansen), Peter E. Christensen and Alexander R. Johansen as educational material for the graduate deep learning course at the Technical University of Denmark (DTU). You can access the full course material here. Inspired by the great Andrej Karpathy.


In this lab we will introduce different ways of learning from sequential data. As an example, we will train a neural network to do language modelling, i.e. predict the next token in a sentence. In the context of natural language processing a token could be a character or a word, but mind you that the concepts introduced here apply to all kinds of sequential data, such as e.g. protein sequences, weather measurements, audio signals or monetary transaction history, just to name a few.

To really get a grasp of what is going on inside the recurrent neural networks that we are about to teach you, we will carry out a substantial part of this exercise in NumPy rather than PyTorch. Once you get a hold of it, we will proceed to the PyTorch implementation.

In this notebook we will show you:

  • How to represent categorical variables in networks
  • How to build a recurrent neural network (RNN) from scratch
  • How to build a LSTM network from scratch
  • How to build a LSTM network in PyTorch

Dataset

For this exercise we will create a simple dataset that we can learn from. We generate sequences of the form:

a b EOS,

a a b b EOS,

a a a a a b b b b b EOS

where EOS is a special character denoting the end of a sequence. The task is to predict the next token t_n, i.e. a, b, EOS or the unknown token UNK given the sequence of tokens t_1, t_2, ..., t_n-1 and we are to process sequences in a sequential manner. As such, the network will need to learn that e.g. 5 bs and an EOS token will follow 5 as.

Results

The RNN takes considerable effort to converge to a nice solution:

RNN loss

The LSTM learns much faster than the RNN:

LSTM loss

And finally, the PyTorch LSTM learns even faster and converges to a better local minimum:

PyTorch LSTM loss

After working your way through these exercises, you should have a better understanding of how RNNs work, how to train them, and what they can be used for. And the conclusion? - use PyTorch.