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Machine Learning for Finance

Machine Learning for Finance

By : James Le , Jannes Klaas
4.1 (59)
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Machine Learning for Finance

Machine Learning for Finance

4.1 (59)
By: James Le , Jannes Klaas

Overview of this book

Machine Learning for Finance explores new advances in machine learning and shows how they can be applied across the financial sector, including insurance, transactions, and lending. This book explains the concepts and algorithms behind the main machine learning techniques and provides example Python code for implementing the models yourself. The book is based on Jannes Klaas’ experience of running machine learning training courses for financial professionals. Rather than providing ready-made financial algorithms, the book focuses on advanced machine learning concepts and ideas that can be applied in a wide variety of ways. The book systematically explains how machine learning works on structured data, text, images, and time series. You'll cover generative adversarial learning, reinforcement learning, debugging, and launching machine learning products. Later chapters will discuss how to fight bias in machine learning. The book ends with an exploration of Bayesian inference and probabilistic programming.
Table of Contents (15 chapters)
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Machine Learning for Finance
Machine Learning for Finance
Contributors
Contributors
Preface
Preface
Other Books You May Enjoy
Other Books You May Enjoy
Free Chapter
1
Neural Networks and Gradient-Based Optimization
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Neural Networks and Gradient-Based Optimization
Our journey in this book
What is machine learning?
Supervised learning
Unsupervised learning
Reinforcement learning
Setting up your workspace
Using Kaggle kernels
Using the AWS deep learning AMI
Approximating functions
A forward pass
A logistic regressor
Optimizing model parameters
Measuring model loss
A deeper network
A brief introduction to Keras
Tensors and the computational graph
Exercises
Summary
2
Applying Machine Learning to Structured Data
Applying Machine Learning to Structured Data
The data
Heuristic, feature-based, and E2E models
The machine learning software stack
The heuristic approach
The feature engineering approach
Preparing the data for the Keras library
Creating predictive models with Keras
A brief primer on tree-based methods
E2E modeling
Exercises
Summary
3
Utilizing Computer Vision
Utilizing Computer Vision
Convolutional Neural Networks
Filters on color images
The building blocks of ConvNets in Keras
More bells and whistles for our neural network
Working with big image datasets
Working with pretrained models
The modularity tradeoff
Computer vision beyond classification
Exercises
Summary
4
Understanding Time Series
Understanding Time Series
Visualization and preparation in pandas
Fast Fourier transformations
Autocorrelation
Establishing a training and testing regime
A note on backtesting
Median forecasting
ARIMA
Kalman filters
Forecasting with neural networks
Conv1D
Dilated and causal convolution
Simple RNN
LSTM
Recurrent dropout
Bayesian deep learning
Exercises
Summary
5
Parsing Textual Data with Natural Language Processing
Parsing Textual Data with Natural Language Processing
An introductory guide to spaCy
Named entity recognition
Part-of-speech (POS) tagging
Rule-based matching
Regular expressions
A text classification task
Preparing the data
Bag-of-words
Topic modeling
Word embeddings
Document similarity with word embeddings
A quick tour of the Keras functional API
Attention
Seq2seq models
Exercises
Summary
6
Using Generative Models
Using Generative Models
Understanding autoencoders
Visualizing latent spaces with t-SNE
Variational autoencoders
VAEs for time series
GANs
Using less data – active learning
SGANs for fraud detection
Exercises
Summary
7
Reinforcement Learning for Financial Markets
Reinforcement Learning for Financial Markets
Catch – a quick guide to reinforcement learning
Markov processes and the bellman equation – A more formal introduction to RL
Advantage actor-critic models
Evolutionary strategies and genetic algorithms
Practical tips for RL engineering
Frontiers of RL
Exercises
Summary
8
Privacy, Debugging, and Launching Your Products
Privacy, Debugging, and Launching Your Products
Debugging data
Debugging your model
Deployment
Performance tips
Exercises
Summary
9
Fighting Bias
Fighting Bias
Sources of unfairness in machine learning
Legal perspectives
Observational fairness
Training to be fair
Causal learning
Interpreting models to ensure fairness
Unfairness as complex system failure
A checklist for developing fair models
Exercises
Summary
10
Bayesian Inference and Probabilistic Programming
Bayesian Inference and Probabilistic Programming
An intuitive guide to Bayesian inference
Summary
Farewell
Further reading
Index
Index

Optimizing model parameters

We've already seen that we need to tweak the weights and biases, collectively called the parameters, of our model in order to arrive at a closer approximation of our desired function.

In other words, we need to look through the space of possible functions that can be represented by our model in order to find a function, Optimizing model parameters, that matches our desired function, f, as closely as possible.

But how would we know how close we are? In fact, since we don't know f, we cannot directly know how close our hypothesis, Optimizing model parameters, is to f. But what we can do is measure how well Optimizing model parameters's outputs match the output of f. The expected outputs of f given X are the labels, y. So, we can try to approximate f by finding a function, Optimizing model parameters, whose outputs are also y given X.

We know that the following is true:

Optimizing model parameters

We also know that:

Optimizing model parameters

We can try to find f by optimizing using the following formula:

Optimizing model parameters

Within this formula, Optimizing model parameters is the space of functions that can be represented by our model, also called the hypothesis space, while D is the distance function, which we use to evaluate how close Optimizing model parameters and y are.

Note

Note: This approach makes a crucial assumption that our data, X, and labels, y, represent our desired function, f. This is not always the case. When our data contains systematic biases, we might gain a function that fits our data well but is different from the one we wanted.

An example of optimizing model parameters comes from human resource management. Imagine you are trying to build a model that predicts the likelihood of a debtor defaulting on their loan, with the intention of using this to decide who should get a loan.

As training data, you can use loan decisions made by human bank managers over the years. However, this presents a problem as these managers might be biased. For instance, minorities, such as black people, have historically had a harder time getting a loan.

With that being said, if we used that training data, our function would also present that bias. You'd end up with a function mirroring or even amplifying human biases, rather than creating a function that is good at predicting who is a good debtor.

It is a commonly made mistake to believe that a neural network will find the intuitive function that we are looking for. It'll actually find the function that best fits the data with no regard for whether that is the desired function or not.

End of Section 6
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