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Main Authors: Yu, Xinglei, Liu, Zhenyang, Nan, Shufeng, Wu, Simo, Fu, Yanwei
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.15938
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author Yu, Xinglei
Liu, Zhenyang
Nan, Shufeng
Wu, Simo
Fu, Yanwei
author_facet Yu, Xinglei
Liu, Zhenyang
Nan, Shufeng
Wu, Simo
Fu, Yanwei
contents Diffusion policies are becoming mainstream in robotic manipulation but suffer from hard negative class imbalance due to uniform sampling and lack of sample difficulty awareness, leading to slow training convergence and frequent inference timeout failures. We propose VADF (Vision-Adaptive Diffusion Policy Framework), a vision-driven dual-adaptive framework that significantly reduces convergence steps and achieves early success in inference, with model-agnostic design enabling seamless integration into any diffusion policy architecture. During training, we introduce Adaptive Loss Network (ALN), a lightweight MLP-based loss predictor that quantifies per-step sample difficulty in real time. Guided by hard negative mining, it performs weighted sampling to prioritize high-loss regions, enabling adaptive weight updates and faster convergence. In inference, we design the Hierarchical Vision Task Segmenter (HVTS), which decomposes high-level task instructions into multi-stage low-level sub-instructions based on visual input. It adaptively segments action sequences into simple and complex subtasks by assigning shorter noise schedules with longer direct execution sequences to simple actions, and longer noise steps with shorter execution sequences to complex ones, thereby dramatically reducing computational overhead and significantly improving the early success rate.
format Preprint
id arxiv_https___arxiv_org_abs_2604_15938
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle VADF: Vision-Adaptive Diffusion Policy Framework for Efficient Robotic Manipulation
Yu, Xinglei
Liu, Zhenyang
Nan, Shufeng
Wu, Simo
Fu, Yanwei
Robotics
Diffusion policies are becoming mainstream in robotic manipulation but suffer from hard negative class imbalance due to uniform sampling and lack of sample difficulty awareness, leading to slow training convergence and frequent inference timeout failures. We propose VADF (Vision-Adaptive Diffusion Policy Framework), a vision-driven dual-adaptive framework that significantly reduces convergence steps and achieves early success in inference, with model-agnostic design enabling seamless integration into any diffusion policy architecture. During training, we introduce Adaptive Loss Network (ALN), a lightweight MLP-based loss predictor that quantifies per-step sample difficulty in real time. Guided by hard negative mining, it performs weighted sampling to prioritize high-loss regions, enabling adaptive weight updates and faster convergence. In inference, we design the Hierarchical Vision Task Segmenter (HVTS), which decomposes high-level task instructions into multi-stage low-level sub-instructions based on visual input. It adaptively segments action sequences into simple and complex subtasks by assigning shorter noise schedules with longer direct execution sequences to simple actions, and longer noise steps with shorter execution sequences to complex ones, thereby dramatically reducing computational overhead and significantly improving the early success rate.
title VADF: Vision-Adaptive Diffusion Policy Framework for Efficient Robotic Manipulation
topic Robotics
url https://arxiv.org/abs/2604.15938