- author = "Jeff Heaton",
- title = "Automated Feature Engineering for Deep Neural Networks with Genetic Programming",
- school = "Computer Science, Nova Southeastern University",
- year = "2017",
- address = "Florida, USA",
- keywords = "genetic algorithms, genetic programming, Applied sciences, Deep neural network, Feature engineering, Artificial intelligence, Computer science",
- isbn13 = "9781369660012",
- language = "English",
-
URL = "
https://search.proquest.com/docview/1889190846?accountid=14511",
-
URL = "https://search.proquest.com/docview/1889190846?pq-origsite=gscholar",
-
URL = "http://nsuworks.nova.edu/gscis_etd/994/",
-
URL = "https://www.researchgate.net/publication/316285310_Automated_Feature_Engineering_for_Deep_Neural_Networks_with_Genetic_Programming",
- size = "202 pages",
-
abstract = "Feature engineering is a process that augments the
feature vector of a machine learning model with
calculated values that are designed to enhance the
accuracy of a model's predictions. Research has shown
that the accuracy of models such as deep neural
networks, support vector machines, and
tree/forest-based algorithms sometimes benefit from
feature engineering. Expressions that combine one or
more of the original features usually create these
engineered features. The choice of the exact structure
of an engineered feature is dependent on the type of
machine learning model in use. Previous research
demonstrated that various model families benefit from
different types of engineered feature. Random forests,
gradient-boosting machines, or other tree-based models
might not see the same accuracy gain that an engineered
feature allowed neural networks, generalized linear
models, or other dot-product based models to achieve on
the same data set.
This dissertation presents a genetic programming-based algorithm that automatically engineers features that increase the accuracy of deep neural networks for some data sets. For a genetic programming algorithm to be effective, it must prioritize the search space and efficiently evaluate what it finds. This dissertation algorithm faced a potential search space composed of all possible mathematical combinations of the original feature vector. Five experiments were designed to guide the search process to efficiently evolve good engineered features. The result of this dissertation is an automated feature engineering (AFE) algorithm that is computationally efficient, even though a neural network is used to evaluate each candidate feature. This approach gave the algorithm a greater opportunity to specifically target deep neural networks in its search for engineered features that improve accuracy. Finally, a sixth experiment empirically demonstrated the degree to which this algorithm improved the accuracy of neural networks on data sets augmented by the algorithm's engineered features.",
-
notes = "
ProQuest Dissertations Publishing, 2017. 10259604.
Supervisor James D. Cannady School code 1191",
