Abstract

Biological Ecosystem Networks (BENs) are webs of biological species (nodes) establishing trophic relationships (links). Experimental confirmation of all possible links is difficult and generates a huge volume of information. Consequently, computational prediction becomes an important goal. Artificial Neural Networks (ANNs) are Machine Learning (ML) algorithms that may be used to predict BENs, using as input Shannon entropy information measures (Shk) of known ecosystems to train them. However, it is difficult to select a priori which ANN topology will have a higher accuracy. Interestingly, Auto Machine Learning (AutoML) methods focus on the automatic selection of the more efficient ML algorithms for specific problems. In this work, a preliminary study of a new approach to AutoML selection of ANNs is proposed for the prediction of BENs. We call it the Net-Net AutoML approach, because it uses for the first time Shk values of both networks involving BENs (networks to be predicted) and ANN topologies (networks to be tested). Twelve types of classifiers have been tested for the Net-Net model including linear, Bayesian, trees-based methods, multilayer perceptrons and deep neuronal networks. The best Net-Net AutoML model for 338,050 outputs of 10 ANN topologies for links of 69 BENs was obtained with a deep fully connected neuronal network, characterized by a test accuracy of 0.866 and a test AUROC of 0.935. This work paves the way for the application of Net-Net AutoML to other systems or ML algorithms.

Highlights

  • A molecular or living complex system can be explained using numerical parameters that quantify information about the structure of the system

  • This is the first report of a Net-Net Automated Machine Learning (AutoML) model for Artificial Neural Networks (ANNs) screening, with the subsequent saving of time and computational resources in the prediction of Complex Networks

  • The Biological Ecosystem Networks (BENs) node pairs and the ANN classifiers that were trained for the prediction of BEN node connectivity were turned into Shk descriptors that encoded information for the BEN nodes and the entire ANN topology

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Summary

Introduction

A molecular or living complex system can be explained using numerical parameters that quantify information about the structure of the system. In the case of complex molecular and living systems, a non-expert may find it difficult to decide a priori which ML algorithms should be selected to develop the model. Ecosystems represent one of the most important examples of complex systems They are a clear example of network-like structures with known procedures to calculate the Shk values[32,33,34]. An AutoML linear model is sought using these indices as input This Net-Net AutoML model could be employed to screen different ANN topologies in order to pre-select the one expected to correctly predict BEN structures before training it

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