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RObotic MAnipulation Network (ROMAN) -- Hybrid Hierarchical Learning for Solving Complex Sequential Tasks

robotics › manipulation

📄 Abstract

Abstract: Solving long sequential tasks poses a significant challenge in embodied artificial intelligence. Enabling a robotic system to perform diverse sequential tasks with a broad range of manipulation skills is an active area of research. In this work, we present a Hybrid Hierarchical Learning framework, the Robotic Manipulation Network (ROMAN), to address the challenge of solving multiple complex tasks over long time horizons in robotic manipulation. ROMAN achieves task versatility and robust failure recovery by integrating behavioural cloning, imitation learning, and reinforcement learning. It consists of a central manipulation network that coordinates an ensemble of various neural networks, each specialising in distinct re-combinable sub-tasks to generate their correct in-sequence actions for solving complex long-horizon manipulation tasks. Experimental results show that by orchestrating and activating these specialised manipulation experts, ROMAN generates correct sequential activations for accomplishing long sequences of sophisticated manipulation tasks and achieving adaptive behaviours beyond demonstrations, while exhibiting robustness to various sensory noises. These results demonstrate the significance and versatility of ROMAN's dynamic adaptability featuring autonomous failure recovery capabilities, and highlight its potential for various autonomous manipulation tasks that demand adaptive motor skills.

Authors (4)

Eleftherios Triantafyllidis

Fernando Acero

Zhaocheng Liu

Zhibin Li

Submitted

June 30, 2023

arXiv Category

cs.RO

arXiv PDF

Key Contributions

Introduces the Robotic Manipulation Network (ROMAN), a Hybrid Hierarchical Learning framework designed to solve complex, long sequential tasks in robotic manipulation. ROMAN integrates behavioral cloning, imitation learning, and reinforcement learning through an ensemble of specialized neural networks, enabling task versatility and robust failure recovery.

Business Value

Enables robots to perform more complex and varied tasks autonomously, increasing automation capabilities in manufacturing, logistics, and other industries, and reducing the need for human intervention in intricate operations.

Paper Metadata

Innovation Type

Algorithmic/Framework

Deployment Feasibility

High - Directly applicable to robotic systems, though requires significant engineering and integration effort.

Limitations Addressed

The challenge of solving long sequential tasks in embodied AI and robotic manipulation. Difficulty in enabling robots to perform diverse manipulation skills and recover from failures.

Performance Gains

Demonstrates ability to generate correct sequential actions for complex long-horizon manipulation tasks by orchestrating specialized experts.

Technical Tags

Robotic ManipulationSequential TasksEmbodied AIHybrid Hierarchical LearningBehavioral CloningImitation LearningReinforcement LearningEnsemble of Neural NetworksSub-task SpecializationLong Horizon TasksFailure Recovery

Research Topics

RoboticsEmbodied AIMachine LearningReinforcement LearningTask Planning

Methods & Architectures

Robotic Manipulation Network (ROMAN)Hybrid Hierarchical LearningBehavioral CloningImitation LearningReinforcement LearningEnsemble Learning Ensemble of Neural Networks

Applications & Tasks

Robotics Automation Manufacturing Logistics Solving long sequential tasks in robotic manipulationEnabling robots to perform diverse manipulation skillsRobust failure recovery in complex tasks Coordinating specialized neural networks for sub-tasksGenerating correct in-sequence actions for long-horizon tasksAchieving task versatility and robust failure recovery

Datasets & Benchmarks

Benchmarks

Experimental results show ROMAN generates correct sequential actions.

Task success rateSequence correctnessRobustness to failures

Related Fields

RoboticsArtificial IntelligenceMachine LearningReinforcement LearningComputer Vision

Keywords

RoboticsManipulationSequential TasksEmbodied AIHierarchical LearningBehavioral CloningImitation LearningReinforcement LearningNeural NetworksTask PlanningAutomationRobotic Control

Academic Context

#Robotics#Embodied AI#Machine Learning#Reinforcement Learning#Task Planning

Commercial Potential

Potential Products

Advanced robotic control systemsModular AI frameworks for robot task executionRobotic automation solutions

Target Industries

ManufacturingLogisticsWarehousingAutomotiveAerospace

Use Case Examples

Robots assembling complex productsAutomated picking and packing in warehousesRobots performing intricate tasks in hazardous environments

Competitive Edge

ROMAN offers a hybrid hierarchical approach that combines multiple learning paradigms (BC, IL, RL) within an ensemble structure, aiming for greater versatility and robustness in long sequential tasks compared to single-method approaches.

Market Opportunity

Large and growing market for industrial automation and advanced robotics.

Revenue Models

Licensing of the ROMAN frameworkdevelopment of custom robotic solutions.

Resource Requirements

Compute Needs

High - Training multiple neural networks and coordinating them requires significant computational resources.

Data Requirements

Requires data for behavioral cloning and imitation learning, and potentially simulation environments for reinforcement learning.

Deployment Constraints

Integration with robotic hardware, real-time control challenges, safety considerations.

Scalability

Scalability depends on the modularity of the network ensemble and the complexity of the tasks.

Production Readiness

Maturity Level

Research

Time to Market

2-5 years

Patent Potential

High

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