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Main Authors: Akcal, Ugur, Kim, Seung Hyun, Yuasa, Mikihisa, Osooli, Hamid, Sun, Jiarui, Sahu, Ribhav, Gazzola, Mattia, Tran, Huy T., Chowdhary, Girish
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.15725
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author Akcal, Ugur
Kim, Seung Hyun
Yuasa, Mikihisa
Osooli, Hamid
Sun, Jiarui
Sahu, Ribhav
Gazzola, Mattia
Tran, Huy T.
Chowdhary, Girish
author_facet Akcal, Ugur
Kim, Seung Hyun
Yuasa, Mikihisa
Osooli, Hamid
Sun, Jiarui
Sahu, Ribhav
Gazzola, Mattia
Tran, Huy T.
Chowdhary, Girish
contents Spiking neural networks (SNNs) and biologically-inspired learning mechanisms are attractive in mobile robotics, where the size and performance of onboard neural network policies are constrained by power and computational budgets. Existing SNN approaches, such as population coding, reward modulation, and hybrid artificial neural network (ANN)-SNN architectures, have shown promising results; however, they face challenges in complex, highly stochastic environments due to SNN sensitivity to hyperparameters and inconsistent gradient signals. To address these challenges, we propose simple spiking actor (S2Act), a computationally lightweight framework that deploys an RL policy using an SNN in three steps: (1) architect an actor-critic model based on an approximated network of rate-based spiking neurons, (2) train the network with gradients using compatible activation functions, and (3) transfer the trained weights into physical parameters of rate-based leaky integrate-and-fire (LIF) neurons for inference and deployment. By globally shaping LIF neuron parameters such that their rate-based responses approximate ReLU activations, S2Act effectively mitigates the vanishing gradient problem, while pre-constraining LIF response curves reduces reliance on complex SNN-specific hyperparameter tuning. We demonstrate our method in two multi-agent stochastic environments (capture-the-flag and parking) that capture the complexity of multi-robot interactions, and deploy our trained policies on physical TurtleBot platforms using Intel's Loihi neuromorphic hardware. Our experimental results show that S2Act outperforms relevant baselines in task performance and real-time inference in nearly all considered scenarios, highlighting its potential for rapid prototyping and efficient real-world deployment of SNN-based RL policies.
format Preprint
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institution arXiv
publishDate 2026
record_format arxiv
spellingShingle S2Act: Simple Spiking Actor
Akcal, Ugur
Kim, Seung Hyun
Yuasa, Mikihisa
Osooli, Hamid
Sun, Jiarui
Sahu, Ribhav
Gazzola, Mattia
Tran, Huy T.
Chowdhary, Girish
Multiagent Systems
Emerging Technologies
Machine Learning
Robotics
Spiking neural networks (SNNs) and biologically-inspired learning mechanisms are attractive in mobile robotics, where the size and performance of onboard neural network policies are constrained by power and computational budgets. Existing SNN approaches, such as population coding, reward modulation, and hybrid artificial neural network (ANN)-SNN architectures, have shown promising results; however, they face challenges in complex, highly stochastic environments due to SNN sensitivity to hyperparameters and inconsistent gradient signals. To address these challenges, we propose simple spiking actor (S2Act), a computationally lightweight framework that deploys an RL policy using an SNN in three steps: (1) architect an actor-critic model based on an approximated network of rate-based spiking neurons, (2) train the network with gradients using compatible activation functions, and (3) transfer the trained weights into physical parameters of rate-based leaky integrate-and-fire (LIF) neurons for inference and deployment. By globally shaping LIF neuron parameters such that their rate-based responses approximate ReLU activations, S2Act effectively mitigates the vanishing gradient problem, while pre-constraining LIF response curves reduces reliance on complex SNN-specific hyperparameter tuning. We demonstrate our method in two multi-agent stochastic environments (capture-the-flag and parking) that capture the complexity of multi-robot interactions, and deploy our trained policies on physical TurtleBot platforms using Intel's Loihi neuromorphic hardware. Our experimental results show that S2Act outperforms relevant baselines in task performance and real-time inference in nearly all considered scenarios, highlighting its potential for rapid prototyping and efficient real-world deployment of SNN-based RL policies.
title S2Act: Simple Spiking Actor
topic Multiagent Systems
Emerging Technologies
Machine Learning
Robotics
url https://arxiv.org/abs/2603.15725