Your search keyword '"Zunino, Rodolfo"' showing total 4 results

1. An approximate randomization-based neural network with dedicated digital architecture for energy-constrained devices.

Author

Ragusa, Edoardo, Gianoglio, Christian, Zunino, Rodolfo, and Gastaldo, Paolo

Subjects

MACHINE learning, COST functions, LEARNING strategies

Abstract

Variable energy constraints affect the implementations of neural networks on battery-operated embedded systems. This paper describes a learning algorithm for randomization-based neural networks with hard-limit activation functions. The approach adopts a novel cost function that balances accuracy and network complexity during training. From an energy-specific perspective, the new learning strategy allows to adjust, dynamically and in real time, the number of operations during the network's forward phase. The proposed learning scheme leads to efficient predictors supported by digital architectures. The resulting digital architecture can switch to approximate computing at run time, in compliance with the available energy budget. Experiments on 10 real-world prediction testbeds confirmed the effectiveness of the learning scheme. Additional tests on limited-resource devices supported the implementation efficiency of the overall design approach. [ABSTRACT FROM AUTHOR]

Published

2023

2. Implementing probabilistic Neural Networks

Author

Ancona, Fabio, Colla, Anna Maria, Rovetta, Stefano, and Zunino, Rodolfo

Published

1997

3. Class-Entropy minimisation networks for domain analysis and rule extraction

Author

Ridella, Sandro, Speroni, Gian Luca, Trebino, Paolo, and Zunino, Rodolfo

Published

1994

4. Random-based networks with dropout for embedded systems.

Author

Ragusa, Edoardo, Gianoglio, Christian, Zunino, Rodolfo, and Gastaldo, Paolo

Subjects

COMPUTATIONAL complexity, INTERNET of things, GENERALIZATION, ALGORITHMS

Abstract

Random-based learning paradigms exhibit efficient training algorithms and remarkable generalization performances. However, the computational cost of the training procedure scales with the cube of the number of hidden neurons. The paper presents a novel training procedure for random-based neural networks, which combines ensemble techniques and dropout regularization. This limits the computational complexity of the training phase without affecting classification performance significantly; the method best fits Internet of Things (IoT) applications. In the training algorithm, one first generates a pool of random neurons; then, an ensemble of independent sub-networks (each including a fraction of the original pool) is trained; finally, the sub-networks are integrated into one classifier. The experimental validation compared the proposed approach with state-of-the-art solutions, by taking into account both generalization performance and computational complexity. To verify the effectiveness in IoT applications, the training procedures were deployed on a pair of commercially available embedded devices. The results showed that the proposed approach overall improved accuracy, with a minor degradation in performance in a few cases. When considering embedded implementations as compared with conventional architectures, the speedup of the proposed method scored up to 20× in IoT devices. [ABSTRACT FROM AUTHOR]

Published

2021