Robotic pick-and-place of novel objects in clutter with multi-affordance grasping and cross-domain image matching (2017-10-03T00:00:00.000000Z)

TL;DR

A robotic pick-and-place system that is capable of grasping and recognizing both known and novel objects in cluttered environments and that handles a wide range of object categories without needing any task-specific training data for novel objects is presented.

Abstract

This article presents a robotic pick-and-place system that is capable of grasping and recognizing both known and novel objects in cluttered environments. The key new feature of the system is that it handles a wide range of object categories without needing any task-specific training data for novel objects. To achieve this, it first uses an object-agnostic grasping framework to map from visual observations to actions: inferring dense pixel-wise probability maps of the affordances for four different grasping primitive actions. It then executes the action with the highest affordance and recognizes picked objects with a cross-domain image classification framework that matches observed images to product images. Since product images are readily available for a wide range of objects (e.g., from the web), the system works out-of-the-box for novel objects without requiring any additional data collection or re-training. Exhaustive experimental results demonstrate that our multi-affordance grasping achieves high success rates for a wide variety of objects in clutter, and our recognition algorithm achieves high accuracy for both known and novel grasped objects. The approach was part of the MIT–Princeton Team system that took first place in the stowing task at the 2017 Amazon Robotics Challenge. All code, datasets, and pre-trained models are available online at http://arc.cs.princeton.edu/

Authors

References49 items

Learning ambidextrous robot grasping policies

Dex-Net 3.0: Computing Robust Vacuum Suction Grasp Targets in Point Clouds Using a New Analytic Model and Deep Learning

Learning Synergies Between Pushing and Grasping with Self-Supervised Deep Reinforcement Learning

Tactile Regrasp: Grasp Adjustments via Simulated Tactile Transformations

GelSlim: A High-Resolution, Compact, Robust, and Calibrated Tactile-sensing Finger

Semantic Segmentation from Limited Training Data

Cartman: The Low-Cost Cartesian Manipulator that Won the Amazon Robotics Challenge

NimbRo picking: Versatile part handling for warehouse automation

Dex-Net 2.0: Deep Learning to Plan Robust Grasps with Synthetic Point Clouds and Analytic Grasp Metrics

SegICP: Integrated deep semantic segmentation and pose estimation

A novel occlusion-free active recognition algorithm for objects in clutter

Supervision via competition: Robot adversaries for learning tasks

Learning Hand-Eye Coordination for Robotic Grasping with Large-Scale Data Collection

Deep unsupervised learning through spatial contrasting

Probabilistic multi-class segmentation for the Amazon Picking Challenge

Multi-view self-supervised deep learning for 6D pose estimation in the Amazon Picking Challenge

What makes ImageNet good for transfer learning?

Team Delft's Robot Winner of the Amazon Picking Challenge 2016

Look-Ahead Before You Leap: End-to-End Active Recognition by Forecasting the Effect of Motion

Learning hand-eye coordination for robotic grasping with deep learning and large-scale data collection

High precision grasp pose detection in dense clutter

Analysis and Observations From the First Amazon Picking Challenge

Deep Residual Learning for Image Recognition

Supersizing self-supervision: Learning to grasp from 50K tries and 700 robot hours

Learning visual similarity for product design with convolutional neural networks

Spatial Transformer Networks

Active recognition and pose estimation of household objects in clutter

Real-time grasp detection using convolutional neural networks

Fully convolutional networks for semantic segmentation

Mobile bin picking with an anthropomorphic service robot

Deep learning for detecting robotic grasps

Indoor Segmentation and Support Inference from RGBD Images

Fast object localization and pose estimation in heavy clutter for robotic bin picking

Data-driven visual similarity for cross-domain image matching

Active vision in robotic systems: A survey of recent developments

SIFT Flow: Dense Correspondence across Scenes and Its Applications

Adapting Visual Category Models to New Domains

ImageNet: A large-scale hierarchical image database

Robotic Grasping of Novel Objects using Vision

Using Experience for Assessing Grasp Reliability

Automatic grasp planning using shape primitives

Robotic grasping and contact: a review

Active and exploratory perception

End-to-End Learning of Object Grasp Poses in the Amazon Robotics Challenge

Robotic pick-and-place of novel objects in clutter with multi-affordance grasping and cross-domain image matching

Siamese Neural Networks for One-Shot Image Recognition

Using Geometry to Detect Grasp Poses in 3D Point Clouds

Automated Construction of Robotic Manipulation Programs

Webpage for code and data