arxiv_ai 89% Match Research Paper Robotics Engineers,Control System Engineers,Researchers in Automation,Smart Environment Developers 20 hours ago

Digital Twin based Automatic Reconfiguration of Robotic Systems in Smart Environments

robotics › sim-to-real

📄 Abstract

Abstract: Robotic systems have become integral to smart environments, enabling applications ranging from urban surveillance and automated agriculture to industrial automation. However, their effective operation in dynamic settings - such as smart cities and precision farming - is challenged by continuously evolving topographies and environmental conditions. Traditional control systems often struggle to adapt quickly, leading to inefficiencies or operational failures. To address this limitation, we propose a novel framework for autonomous and dynamic reconfiguration of robotic controllers using Digital Twin technology. Our approach leverages a virtual replica of the robot's operational environment to simulate and optimize movement trajectories in response to real-world changes. By recalculating paths and control parameters in the Digital Twin and deploying the updated code to the physical robot, our method ensures rapid and reliable adaptation without manual intervention. This work advances the integration of Digital Twins in robotics, offering a scalable solution for enhancing autonomy in smart, dynamic environments.

Key Contributions

Proposes a novel framework for autonomous and dynamic reconfiguration of robotic controllers using Digital Twin technology. It leverages a virtual replica to simulate and optimize robot behavior in response to real-world changes, enabling rapid adaptation without manual intervention.

Business Value

Increases the efficiency, reliability, and operational uptime of robotic systems in dynamic environments, reducing downtime and maintenance costs.

Paper Metadata

Innovation Type

Framework and Methodology Development

Deployment Feasibility

High, integrates simulation with physical deployment.

Limitations Addressed

Struggles of traditional control systems to adapt quickly to dynamic environments, leading to inefficiencies or failures.

Performance Gains

Ensures rapid and reliable adaptation of robotic systems to real-world changes.

Technical Tags

Digital TwinRobotic SystemsAutomatic ReconfigurationSmart EnvironmentsDynamic AdaptationVirtual ReplicaPath PlanningControl ParametersReal-time AdaptationAutonomous Control

Research Topics

Dynamic Reconfiguration of Robotic SystemsDigital Twin Technology for RoboticsAutonomous Adaptation in Smart EnvironmentsImproving Robot Robustness in Dynamic Settings

Methods & Architectures

Digital Twin frameworkSimulation and optimization in virtual replicaRecalculation of paths and control parametersDeployment of updated code to physical robotAutonomous reconfiguration Digital Twin modelsControl systems

Applications & Tasks

Robotics Smart Cities Industrial Automation Agriculture Urban Surveillance Adapting robotic systems to continuously evolving environmentsInefficiencies and failures due to slow adaptation in dynamic settings Autonomous reconfiguration of robotic controllersDynamic path planningReal-time adaptation of robot behavior

Related Fields

RoboticsDigital TwinsControl SystemsInternet of Things (IoT)Smart ManufacturingSimulation

Keywords

digital twinroboticsreconfigurationsmart environmentsdynamic adaptationautonomous controlpath planningcontrol parametersreal-time adaptationvirtual replica

Academic Context

#Dynamic Reconfiguration of Robotic Systems#Digital Twin Technology for Robotics#Autonomous Adaptation in Smart Environments#Improving Robot Robustness in Dynamic Settings

Commercial Potential

Potential Products

Dynamic control systems for robotsDigital Twin platforms for robotic simulation and deploymentAutomated robot fleet management solutions

Target Industries

ManufacturingLogisticsAgricultureSmart CitiesConstruction

Use Case Examples

A robot in a smart city dynamically adjusting its patrol route due to unexpected road closuresAn agricultural robot adapting its path in a field based on changing crop growth and terrain conditions

Competitive Edge

Provides a proactive and autonomous approach to robot adaptation using Digital Twins, overcoming the limitations of reactive or manual control systems.

Market Opportunity

Growing market for industrial automation, IoT, and smart environment solutions.

Revenue Models

Licensing of Digital Twin softwaredevelopment of integrated robotic solutions.

Resource Requirements

Compute Needs

High (for Digital Twin simulation and real-time control)

Data Requirements

Real-time sensor data from the environment and the robot.

Deployment Constraints

Accuracy of the Digital Twin model, real-time data synchronization, computational resources for simulation and control.

Scalability

Scalable to complex environments and multiple robots, provided accurate Digital Twin models.

Regulatory Considerations

Safety standards for autonomous systemsdata security for Digital Twins.

Production Readiness

Maturity Level

Research/Framework

Time to Market

2-4 years

Patent Potential

High (for the Digital Twin-based reconfiguration framework)

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