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Main Authors: Ortner, Thomas, Petschenig, Horst, Vasilopoulos, Athanasios, Renner, Roland, Brglez, Špela, Limbacher, Thomas, Piñero, Enrique, Barranco, Alejandro Linares, Pantazi, Angeliki, Legenstein, Robert
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.05141
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author Ortner, Thomas
Petschenig, Horst
Vasilopoulos, Athanasios
Renner, Roland
Brglez, Špela
Limbacher, Thomas
Piñero, Enrique
Barranco, Alejandro Linares
Pantazi, Angeliki
Legenstein, Robert
author_facet Ortner, Thomas
Petschenig, Horst
Vasilopoulos, Athanasios
Renner, Roland
Brglez, Špela
Limbacher, Thomas
Piñero, Enrique
Barranco, Alejandro Linares
Pantazi, Angeliki
Legenstein, Robert
contents There is a growing demand for low-power, autonomously learning artificial intelligence (AI) systems that can be applied at the edge and rapidly adapt to the specific situation at deployment site. However, current AI models struggle in such scenarios, often requiring extensive fine-tuning, computational resources, and data. In contrast, humans can effortlessly adjust to new tasks by transferring knowledge from related ones. The concept of learning-to-learn (L2L) mimics this process and enables AI models to rapidly adapt with only little computational effort and data. In-memory computing neuromorphic hardware (NMHW) is inspired by the brain's operating principles and mimics its physical co-location of memory and compute. In this work, we pair L2L with in-memory computing NMHW based on phase-change memory devices to build efficient AI models that can rapidly adapt to new tasks. We demonstrate the versatility of our approach in two scenarios: a convolutional neural network performing image classification and a biologically-inspired spiking neural network generating motor commands for a real robotic arm. Both models rapidly learn with few parameter updates. Deployed on the NMHW, they perform on-par with their software equivalents. Moreover, meta-training of these models can be performed in software with high-precision, alleviating the need for accurate hardware models.
format Preprint
id arxiv_https___arxiv_org_abs_2405_05141
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Learning-to-learn enables rapid learning with phase-change memory-based in-memory computing
Ortner, Thomas
Petschenig, Horst
Vasilopoulos, Athanasios
Renner, Roland
Brglez, Špela
Limbacher, Thomas
Piñero, Enrique
Barranco, Alejandro Linares
Pantazi, Angeliki
Legenstein, Robert
Neural and Evolutionary Computing
Machine Learning
There is a growing demand for low-power, autonomously learning artificial intelligence (AI) systems that can be applied at the edge and rapidly adapt to the specific situation at deployment site. However, current AI models struggle in such scenarios, often requiring extensive fine-tuning, computational resources, and data. In contrast, humans can effortlessly adjust to new tasks by transferring knowledge from related ones. The concept of learning-to-learn (L2L) mimics this process and enables AI models to rapidly adapt with only little computational effort and data. In-memory computing neuromorphic hardware (NMHW) is inspired by the brain's operating principles and mimics its physical co-location of memory and compute. In this work, we pair L2L with in-memory computing NMHW based on phase-change memory devices to build efficient AI models that can rapidly adapt to new tasks. We demonstrate the versatility of our approach in two scenarios: a convolutional neural network performing image classification and a biologically-inspired spiking neural network generating motor commands for a real robotic arm. Both models rapidly learn with few parameter updates. Deployed on the NMHW, they perform on-par with their software equivalents. Moreover, meta-training of these models can be performed in software with high-precision, alleviating the need for accurate hardware models.
title Learning-to-learn enables rapid learning with phase-change memory-based in-memory computing
topic Neural and Evolutionary Computing
Machine Learning
url https://arxiv.org/abs/2405.05141