{"title":"IMRL:整合视觉、物理、时间和几何表征,增强食物获取能力","authors":"Rui Liu, Zahiruddin Mahammad, Amisha Bhaskar, Pratap Tokekar","doi":"arxiv-2409.12092","DOIUrl":null,"url":null,"abstract":"Robotic assistive feeding holds significant promise for improving the quality\nof life for individuals with eating disabilities. However, acquiring diverse\nfood items under varying conditions and generalizing to unseen food presents\nunique challenges. Existing methods that rely on surface-level geometric\ninformation (e.g., bounding box and pose) derived from visual cues (e.g.,\ncolor, shape, and texture) often lacks adaptability and robustness, especially\nwhen foods share similar physical properties but differ in visual appearance.\nWe employ imitation learning (IL) to learn a policy for food acquisition.\nExisting methods employ IL or Reinforcement Learning (RL) to learn a policy\nbased on off-the-shelf image encoders such as ResNet-50. However, such\nrepresentations are not robust and struggle to generalize across diverse\nacquisition scenarios. To address these limitations, we propose a novel\napproach, IMRL (Integrated Multi-Dimensional Representation Learning), which\nintegrates visual, physical, temporal, and geometric representations to enhance\nthe robustness and generalizability of IL for food acquisition. Our approach\ncaptures food types and physical properties (e.g., solid, semi-solid, granular,\nliquid, and mixture), models temporal dynamics of acquisition actions, and\nintroduces geometric information to determine optimal scooping points and\nassess bowl fullness. IMRL enables IL to adaptively adjust scooping strategies\nbased on context, improving the robot's capability to handle diverse food\nacquisition scenarios. Experiments on a real robot demonstrate our approach's\nrobustness and adaptability across various foods and bowl configurations,\nincluding zero-shot generalization to unseen settings. Our approach achieves\nimprovement up to $35\\%$ in success rate compared with the best-performing\nbaseline.","PeriodicalId":501031,"journal":{"name":"arXiv - CS - Robotics","volume":"34 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-09-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"IMRL: Integrating Visual, Physical, Temporal, and Geometric Representations for Enhanced Food Acquisition\",\"authors\":\"Rui Liu, Zahiruddin Mahammad, Amisha Bhaskar, Pratap Tokekar\",\"doi\":\"arxiv-2409.12092\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Robotic assistive feeding holds significant promise for improving the quality\\nof life for individuals with eating disabilities. However, acquiring diverse\\nfood items under varying conditions and generalizing to unseen food presents\\nunique challenges. Existing methods that rely on surface-level geometric\\ninformation (e.g., bounding box and pose) derived from visual cues (e.g.,\\ncolor, shape, and texture) often lacks adaptability and robustness, especially\\nwhen foods share similar physical properties but differ in visual appearance.\\nWe employ imitation learning (IL) to learn a policy for food acquisition.\\nExisting methods employ IL or Reinforcement Learning (RL) to learn a policy\\nbased on off-the-shelf image encoders such as ResNet-50. However, such\\nrepresentations are not robust and struggle to generalize across diverse\\nacquisition scenarios. To address these limitations, we propose a novel\\napproach, IMRL (Integrated Multi-Dimensional Representation Learning), which\\nintegrates visual, physical, temporal, and geometric representations to enhance\\nthe robustness and generalizability of IL for food acquisition. Our approach\\ncaptures food types and physical properties (e.g., solid, semi-solid, granular,\\nliquid, and mixture), models temporal dynamics of acquisition actions, and\\nintroduces geometric information to determine optimal scooping points and\\nassess bowl fullness. IMRL enables IL to adaptively adjust scooping strategies\\nbased on context, improving the robot's capability to handle diverse food\\nacquisition scenarios. Experiments on a real robot demonstrate our approach's\\nrobustness and adaptability across various foods and bowl configurations,\\nincluding zero-shot generalization to unseen settings. 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引用次数: 0
摘要
机器人辅助喂食为改善进食残疾人士的生活质量带来了巨大希望。然而,在不同条件下获取不同的食物并将其推广到未见过的食物上,这带来了独特的挑战。现有的方法依赖于从视觉线索(如颜色、形状和纹理)中提取的表面级几何信息(如边界框和姿势),这些方法往往缺乏适应性和鲁棒性,尤其是当食物具有相似的物理特性但视觉外观不同时。然而,这种方法并不稳健,很难在不同的获取场景中通用。为了解决这些局限性,我们提出了一种新方法--IMRL(综合多维表征学习),它整合了视觉、物理、时间和几何表征,以增强用于食物获取的 IL 的鲁棒性和泛化能力。我们的方法捕捉食物类型和物理特性(如固体、半固体、颗粒状、液体和混合物),建立获取动作的时间动态模型,并引入几何信息以确定最佳舀食点和评估碗的饱满度。IMRL使IL能够根据上下文自适应地调整舀取策略,从而提高机器人处理各种食物获取场景的能力。在真实机器人上进行的实验证明了我们的方法在各种食物和碗配置中的稳健性和适应性,包括对未知环境的零点泛化。与表现最好的基准相比,我们的方法在成功率上提高了 35%。
IMRL: Integrating Visual, Physical, Temporal, and Geometric Representations for Enhanced Food Acquisition
Robotic assistive feeding holds significant promise for improving the quality
of life for individuals with eating disabilities. However, acquiring diverse
food items under varying conditions and generalizing to unseen food presents
unique challenges. Existing methods that rely on surface-level geometric
information (e.g., bounding box and pose) derived from visual cues (e.g.,
color, shape, and texture) often lacks adaptability and robustness, especially
when foods share similar physical properties but differ in visual appearance.
We employ imitation learning (IL) to learn a policy for food acquisition.
Existing methods employ IL or Reinforcement Learning (RL) to learn a policy
based on off-the-shelf image encoders such as ResNet-50. However, such
representations are not robust and struggle to generalize across diverse
acquisition scenarios. To address these limitations, we propose a novel
approach, IMRL (Integrated Multi-Dimensional Representation Learning), which
integrates visual, physical, temporal, and geometric representations to enhance
the robustness and generalizability of IL for food acquisition. Our approach
captures food types and physical properties (e.g., solid, semi-solid, granular,
liquid, and mixture), models temporal dynamics of acquisition actions, and
introduces geometric information to determine optimal scooping points and
assess bowl fullness. IMRL enables IL to adaptively adjust scooping strategies
based on context, improving the robot's capability to handle diverse food
acquisition scenarios. Experiments on a real robot demonstrate our approach's
robustness and adaptability across various foods and bowl configurations,
including zero-shot generalization to unseen settings. Our approach achieves
improvement up to $35\%$ in success rate compared with the best-performing
baseline.