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Main Authors: Zhou, Yulin, Lin, Yuankai, Peng, Fanzhe, Chen, Jiahui, Huang, Kaiji, Yang, Hua, Yin, Zhouping
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.12410
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author Zhou, Yulin
Lin, Yuankai
Peng, Fanzhe
Chen, Jiahui
Huang, Kaiji
Yang, Hua
Yin, Zhouping
author_facet Zhou, Yulin
Lin, Yuankai
Peng, Fanzhe
Chen, Jiahui
Huang, Kaiji
Yang, Hua
Yin, Zhouping
contents Standard imitation learning (IL) methods have achieved considerable success in robotics, yet often rely on the Markov assumption, which falters in long-horizon tasks where history is crucial for resolving perceptual ambiguity. This limitation stems not only from a conceptual gap but also from a fundamental computational barrier: prevailing architectures like Transformers are often constrained by quadratic complexity, rendering the processing of long, high-dimensional observation sequences infeasible. To overcome this dual challenge, we introduce Mamba Temporal Imitation Learning (MTIL). Our approach represents a new paradigm for robotic learning, which we frame as a practical synthesis of World Model and Dynamical System concepts. By leveraging the linear-time recurrent dynamics of State Space Models (SSMs), MTIL learns an implicit, action-oriented world model that efficiently encodes the entire trajectory history into a compressed, evolving state. This allows the policy to be conditioned on a comprehensive temporal context, transcending the confines of Markovian approaches. Through extensive experiments on simulated benchmarks (ACT, Robomimic, LIBERO) and on challenging real-world tasks, MTIL demonstrates superior performance against SOTA methods like ACT and Diffusion Policy, particularly in resolving long-term temporal ambiguities. Our findings not only affirm the necessity of full temporal context but also validate MTIL as a powerful and a computationally feasible approach for learning long-horizon, non-Markovian behaviors from high-dimensional observations.
format Preprint
id arxiv_https___arxiv_org_abs_2505_12410
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle MTIL: Encoding Full History with Mamba for Temporal Imitation Learning
Zhou, Yulin
Lin, Yuankai
Peng, Fanzhe
Chen, Jiahui
Huang, Kaiji
Yang, Hua
Yin, Zhouping
Robotics
I.2.9
Standard imitation learning (IL) methods have achieved considerable success in robotics, yet often rely on the Markov assumption, which falters in long-horizon tasks where history is crucial for resolving perceptual ambiguity. This limitation stems not only from a conceptual gap but also from a fundamental computational barrier: prevailing architectures like Transformers are often constrained by quadratic complexity, rendering the processing of long, high-dimensional observation sequences infeasible. To overcome this dual challenge, we introduce Mamba Temporal Imitation Learning (MTIL). Our approach represents a new paradigm for robotic learning, which we frame as a practical synthesis of World Model and Dynamical System concepts. By leveraging the linear-time recurrent dynamics of State Space Models (SSMs), MTIL learns an implicit, action-oriented world model that efficiently encodes the entire trajectory history into a compressed, evolving state. This allows the policy to be conditioned on a comprehensive temporal context, transcending the confines of Markovian approaches. Through extensive experiments on simulated benchmarks (ACT, Robomimic, LIBERO) and on challenging real-world tasks, MTIL demonstrates superior performance against SOTA methods like ACT and Diffusion Policy, particularly in resolving long-term temporal ambiguities. Our findings not only affirm the necessity of full temporal context but also validate MTIL as a powerful and a computationally feasible approach for learning long-horizon, non-Markovian behaviors from high-dimensional observations.
title MTIL: Encoding Full History with Mamba for Temporal Imitation Learning
topic Robotics
I.2.9
url https://arxiv.org/abs/2505.12410