# Operational Neural Networks

**Authors:** Serkan Kiranyaz, Turker Ince, Alexandros Iosifidis, Moncef Gabbouj

arXiv: 1902.11106 · 2019-10-21

## TL;DR

Operational Neural Networks (ONNs) introduce heterogeneous neurons with diverse operators, enhancing learning of complex, nonlinear functions with fewer resources compared to traditional ANNs and CNNs.

## Contribution

This paper proposes ONNs, a novel neural network model with heterogeneous neurons and operators, improving learning performance on complex problems with minimal network complexity.

## Key findings

- ONNs outperform traditional ANNs and CNNs on challenging problems.
- ONNs require fewer neurons and layers to achieve superior results.
- A new training method effectively propagates errors through operational layers.

## Abstract

Feed-forward, fully-connected Artificial Neural Networks (ANNs) or the so-called Multi-Layer Perceptrons (MLPs) are well-known universal approximators. However, their learning performance varies significantly depending on the function or the solution space that they attempt to approximate. This is mainly because of their homogenous configuration based solely on the linear neuron model. Therefore, while they learn very well those problems with a monotonous, relatively simple and linearly separable solution space, they may entirely fail to do so when the solution space is highly nonlinear and complex. Sharing the same linear neuron model with two additional constraints (local connections and weight sharing), this is also true for the conventional Convolutional Neural Networks (CNNs) and, it is, therefore, not surprising that in many challenging problems only the deep CNNs with a massive complexity and depth can achieve the required diversity and the learning performance. In order to address this drawback and also to accomplish a more generalized model over the convolutional neurons, this study proposes a novel network model, called Operational Neural Networks (ONNs), which can be heterogeneous and encapsulate neurons with any set of operators to boost diversity and to learn highly complex and multi-modal functions or spaces with minimal network complexity and training data. Finally, a novel training method is formulated to back-propagate the error through the operational layers of ONNs. Experimental results over highly challenging problems demonstrate the superior learning capabilities of ONNs even with few neurons and hidden layers.

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Source: https://tomesphere.com/paper/1902.11106