Andrey Kurenkov scite author profile

Tool manipulation is vital for facilitating robots to complete challenging task goals. It requires reasoning about the desired effect of the task and thus properly grasping and manipulating the tool to achieve the task. Task-agnostic grasping optimizes for grasp robustness while ignoring crucial taskspecific constraints. In this paper, we propose the Task-Oriented Grasping Network (TOG-Net) to jointly optimize both taskoriented grasping of a tool and the manipulation policy for that tool. The training process of the model is based on largescale simulated self-supervision with procedurally generated tool objects. We perform both simulated and real-world experiments on two tool-based manipulation tasks: sweeping and hammering. Our model achieves overall 71.1% task success rate for sweeping and 80.0% task success rate for hammering. Supplementary material is available at: bit.ly/task-oriented-grasp.

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Mechanical Search: Multi-Step Retrieval of a Target Object Occluded by Clutter

Danielczuk

Kurenkov

Balakrishna

et al. 2019

111

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When operating in unstructured environments such as warehouses, homes, and retail centers, robots are frequently required to interactively search for and retrieve specific objects from cluttered bins, shelves, or tables. Mechanical Search describes the class of tasks where the goal is to locate and extract a known target object. In this paper, we formalize Mechanical Search and study a version where distractor objects are heaped over the target object in a bin. The robot uses an RGBD perception system and control policies to iteratively select, parameterize, and perform one of 3 actions -push, suction, grasp -until the target object is extracted, or either a time limit is exceeded, or no high confidence push or grasp is available. We present a study of 5 algorithmic policies for mechanical search, with 15,000 simulated trials and 300 physical trials for heaps ranging from 10 to 20 objects. Results suggest that success can be achieved in this long-horizon task with algorithmic policies in over 95% of instances and that the number of actions required scales approximately linearly with the size of the heap. Code and supplementary material can be found at http://ai.stanford.edu/mech-search. * Authors have contributed equally and names are in alphabetical order.

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DeformNet: Free-Form Deformation Network for 3D Shape Reconstruction from a Single Image

Kurenkov

Garg

et al. 2018

126

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3D reconstruction from a single image is a key problem in multiple applications ranging from robotic manipulation to augmented reality. Prior methods have tackled this problem through generative models which predict 3D reconstructions as voxels or point clouds. However, these methods can be computationally expensive and miss fine details. We introduce a new differentiable layer for 3D data deformation and use it in DEFORMNET to learn a model for 3D reconstructionthrough-deformation. DEFORMNET takes an image input, searches the nearest shape template from a database, and deforms the template to match the query image. We evaluate our approach on the ShapeNet dataset and show that -(a) the Free-Form Deformation layer is a powerful new building block for Deep Learning models that manipulate 3D data (b) DEFORMNET uses this FFD layer combined with shape retrieval for smooth and detail-preserving 3D reconstruction of qualitatively plausible point clouds with respect to a single query image (c) compared to other state-of-the-art 3D reconstruction methods, DEFORMNET quantitatively matches or outperforms their benchmarks by significant margins. For more information, visit: https://deformnet-site.github.io/DeformNet-website/.

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Visuomotor Mechanical Search: Learning to Retrieve Target Objects in Clutter

Kurenkov

Taglic

Kulkarni

et al. 2020

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When searching for objects in cluttered environments, it is often necessary to perform complex interactions in order to move occluding objects out of the way and fully reveal the object of interest and make it graspable. Due to the complexity of the physics involved and the lack of accurate models of the clutter, planning and controlling precise predefined interactions with accurate outcome is extremely hard, when not impossible. In problems where accurate (forward) models are lacking, Deep Reinforcement Learning (RL) has shown to be a viable solution to map observations (e.g. images) to good interactions in the form of close-loop visuomotor policies. However, Deep RL is sample inefficient and fails when applied directly to the problem of unoccluding objects based on images. In this work we present a novel Deep RL procedure that combines i) teacheraided exploration, ii) a critic with privileged information, and iii) mid-level representations, resulting in sample efficient and effective learning for the problem of uncovering a target object occluded by a heap of unknown objects. Our experiments show that our approach trains faster and converges to more efficient uncovering solutions than baselines and ablations, and that our uncovering policies lead to an average improvement in the graspability of the target object, facilitating downstream retrieval applications.

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Guest Editorial Open Discussion of Robot Grasping Benchmarks, Protocols, and Metrics

Mahler

Platt

Rodríguez

et al. 2018

IEEE Trans. Automat. Sci. Eng.

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Andrey Kurenkov

Learning task-oriented grasping for tool manipulation from simulated self-supervision

Mechanical Search: Multi-Step Retrieval of a Target Object Occluded by Clutter

DeformNet: Free-Form Deformation Network for 3D Shape Reconstruction from a Single Image

Visuomotor Mechanical Search: Learning to Retrieve Target Objects in Clutter

Guest Editorial Open Discussion of Robot Grasping Benchmarks, Protocols, and Metrics

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