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Toward Humanoid Brain-Body Co-design: Joint Optimization of Control and Morphology for Fall Recovery

robotics › sim-to-real

📄 Abstract

Abstract: Humanoid robots represent a central frontier in embodied intelligence, as their anthropomorphic form enables natural deployment in humans' workspace. Brain-body co-design for humanoids presents a promising approach to realizing this potential by jointly optimizing control policies and physical morphology. Within this context, fall recovery emerges as a critical capability. It not only enhances safety and resilience but also integrates naturally with locomotion systems, thereby advancing the autonomy of humanoids. In this paper, we propose RoboCraft, a scalable humanoid co-design framework for fall recovery that iteratively improves performance through the coupled updates of control policy and morphology. A shared policy pretrained across multiple designs is progressively finetuned on high-performing morphologies, enabling efficient adaptation without retraining from scratch. Concurrently, morphology search is guided by human-inspired priors and optimization algorithms, supported by a priority buffer that balances reevaluation of promising candidates with the exploration of novel designs. Experiments show that \ourmethod{} achieves an average performance gain of 44.55% on seven public humanoid robots, with morphology optimization drives at least 40% of improvements in co-designing four humanoid robots, underscoring the critical role of humanoid co-design.

Authors (4)

Bo Yue

Sheng Xu

Kui Jia

Guiliang Liu

Submitted

October 25, 2025

arXiv Category

cs.RO

arXiv PDF

Key Contributions

This paper introduces RoboCraft, a scalable framework for humanoid brain-body co-design focused on fall recovery. It enables joint optimization of control policies and physical morphology through iterative updates, leveraging shared policy pretraining and human-inspired priors to efficiently adapt and improve robot performance and resilience.

Business Value

Enables the development of safer, more capable humanoid robots for deployment in human environments, such as logistics, manufacturing, and elder care, reducing risks and increasing operational efficiency.

Paper Metadata

Innovation Type

Framework Development

Deployment Feasibility

Low. Requires significant expertise in robotics, control systems, and ML. Physical robot development and testing are complex and expensive.

Limitations Addressed

Difficulty in designing humanoids that are both agile and robust, particularly in dynamic tasks like fall recovery, by treating control and morphology design separately.

Performance Gains

Improved fall recovery capabilities and overall robot resilience through optimized morphology and control.

Technical Tags

Humanoid RobotsEmbodied IntelligenceBrain-Body Co-designFall RecoveryControl Policy OptimizationMorphology OptimizationSim-to-Real TransferReinforcement Learning

Research Topics

RoboticsEmbodied AIControl SystemsMachine LearningHumanoid Robotics

Methods & Architectures

RoboCraft frameworkIterative co-design (control & morphology)Shared policy pretrainingProgressive finetuningHuman-inspired priorsOptimization algorithms Deep Reinforcement Learning PoliciesOptimized Robot Morphology

Applications & Tasks

Robotics Humanoid Robots Industrial Automation Assistive Robotics Robot ControlRobot DesignDynamic StabilityFall Prevention/Recovery Jointly optimizing humanoid robot control and morphologyEnabling robust fall recoveryImproving humanoid robot resilience

Related Fields

RoboticsControl TheoryMachine LearningMechanical EngineeringArtificial Intelligence

Keywords

Humanoid RobotsEmbodied IntelligenceBrain-Body Co-designFall RecoveryRobotics ControlMorphology OptimizationReinforcement LearningSim-to-RealRoboCraftRobot Design

Academic Context

#Robotics#Embodied AI#Control Systems#Machine Learning#Humanoid Robotics

Commercial Potential

Potential Products

Advanced humanoid robot platformsModular robot design kitsSimulation environments for robot development

Target Industries

RoboticsManufacturingLogisticsHealthcareAerospace

Use Case Examples

Humanoid robots performing tasks in warehousesRobots assisting in elder care facilitiesRobots operating in hazardous environments

Competitive Edge

Offers a unified framework for co-designing control and morphology, addressing a key challenge in creating robust and adaptable humanoid robots.

Market Opportunity

Rapidly growing market for advanced robotics and automation.

Revenue Models

Licensing of robot designs and control softwaresale of humanoid robot platforms.

Resource Requirements

Compute Needs

Very High (for simulation and training)

Data Requirements

Simulation environments, potentially real-world robot data.

Deployment Constraints

High cost of hardware, complexity of integration, safety concerns in human environments.

Scalability

The framework is designed to be scalable, allowing for exploration of diverse morphologies and control strategies.

Regulatory Considerations

Safety standards for human-robot interactionethical guidelines for autonomous systems.

Production Readiness

Maturity Level

Research Framework

Time to Market

5-10 years for widespread commercial deployment

Patent Potential

High potential for patents on novel robot designs, control algorithms, and co-design methodologies.

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