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Robotic Manipulation via Imitation Learning: Taxonomy, Evolution, Benchmark, and Challenges
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Robotic Manipulation via Imitation Learning: Taxonomy, Evolution, Benchmark, and Challenges
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Robotic Manipulation (RM) is central to the advancement of autonomous robots, enabling them to interact with and manipulate objects in real-world environments. This survey focuses on RM methodologies that leverage imitation learning, a powerful technique that allows robots to learn complex manipulation skills by mimicking human demonstrations. We identify and analyze the most influential studies in this domain, selected based on community impact and intrinsic quality. For each paper, we provide a structured summary, covering the research purpose, technical implementation, hierarchical classification, input formats, key priors, strengths and limitations, and citation metrics. Additionally, we trace the chronological development of imitation learning techniques within RM policy (RMP), offering a timeline of key technological advancements. Where available, we report benchmark results and perform quantitative evaluations to compare existing methods. By synthesizing these insights, this review provides a comprehensive resource for researchers and practitioners, highlighting both the state of the art and the challenges that lie ahead in the field of robotic manipulation through imitation learning.
Forward citations
Cited by 3 Pith papers
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PriGo: Test-Time Primitive Guidance to Diffusion and Flow Policies for Adaptive Robotic Manipulation
A lightweight primitive classifier and differentiable guidance mechanism improve pretrained diffusion and flow manipulation policies by 3–7 points at test time without retraining.
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Learning Multi-Modal Trajectory Policies for Data-Efficient Robotic Manipulation
MATE is a multi-modal MoE trajectory policy using a cosine router and stochastic noise to improve expert balance, reporting 4.75% higher average success rate than prior methods on LIBERO under data scarcity.
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Decoupling Semantics and Geometric Grounding: Spatial Visual Prompts for Language-Conditioned Imitation Learning
SVP-IL decouples semantic reasoning from geometric grounding in vision-language-action models by injecting zero-shot spatial masks as explicit prompts into a continuous action generator, yielding higher success on amb...
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