arxiv_ml 90% Match Research Paper Robotics Engineers,AI Researchers,Aerospace Engineers,Defense Contractors 2 weeks ago

Onboard Mission Replanning for Adaptive Cooperative Multi-Robot Systems

robotics › multi-agent

📄 Abstract

Abstract: Cooperative autonomous robotic systems have significant potential for executing complex multi-task missions across space, air, ground, and maritime domains. But they commonly operate in remote, dynamic and hazardous environments, requiring rapid in-mission adaptation without reliance on fragile or slow communication links to centralised compute. Fast, on-board replanning algorithms are therefore needed to enhance resilience. Reinforcement Learning shows strong promise for efficiently solving mission planning tasks when formulated as Travelling Salesperson Problems (TSPs), but existing methods: 1) are unsuitable for replanning, where agents do not start at a single location; 2) do not allow cooperation between agents; 3) are unable to model tasks with variable durations; or 4) lack practical considerations for on-board deployment. Here we define the Cooperative Mission Replanning Problem as a novel variant of multiple TSP with adaptations to overcome these issues, and develop a new encoder/decoder-based model using Graph Attention Networks and Attention Models to solve it effectively and efficiently. Using a simple example of cooperative drones, we show our replanner consistently (90% of the time) maintains performance within 10% of the state-of-the-art LKH3 heuristic solver, whilst running 85-370 times faster on a Raspberry Pi. This work paves the way for increased resilience in autonomous multi-agent systems.

Authors (6)

Elim Kwan

Rehman Qureshi

Liam Fletcher

Colin Laganier

Victoria Nockles

Richard Walters

Submitted

June 6, 2025

arXiv Category

cs.RO

arXiv PDF

Key Contributions

This paper addresses onboard mission replanning for cooperative multi-robot systems operating in remote, dynamic environments. It defines a novel 'Cooperative Mission Replanning Problem' as a variant of the Multiple TSP, overcoming limitations of existing RL methods by allowing agents to start at different locations, enabling cooperation, modeling variable task durations, and incorporating practical on-board deployment considerations.

Business Value

Enhances the resilience and adaptability of autonomous robotic systems, enabling them to perform complex missions in challenging environments with reduced reliance on external communication, crucial for exploration, disaster response, and defense.

Paper Metadata

Innovation Type

Problem Formulation & Methodology

Deployment Feasibility

Moderate, requires significant onboard computational power and robust RL algorithms.

Limitations Addressed

Existing RL methods for mission planning are unsuitable for replanning (non-single start location), do not allow cooperation, cannot model variable task durations, and lack practical on-board deployment considerations.

Technical Tags

multi-robot systemsmission replanningreinforcement learningcooperative autonomyon-board computationdynamic environmentstraveling salesman problemresilienceadaptive systemsautonomous systems

Research Topics

Multi-Agent SystemsRoboticsReinforcement LearningMission PlanningAutonomous Systems

Methods & Architectures

Reinforcement LearningMission ReplanningCooperative Mission Replanning Problem formulationMultiple TSP variants Reinforcement Learning agentsMulti-Agent Systems

Applications & Tasks

Robotics Aerospace Maritime Operations Ground Exploration Search and Rescue Mission PlanningReplanning in Dynamic EnvironmentsCooperative Task Execution Onboard mission replanning for cooperative multi-robot systemsAdapting to dynamic and hazardous environmentsExecuting complex multi-task missions

Related Fields

Operations ResearchArtificial IntelligenceControl TheoryDistributed Systems

Keywords

Multi-Robot SystemsMission ReplanningReinforcement LearningCooperative AutonomyOn-board PlanningDynamic EnvironmentsTSPRoboticsAutonomous SystemsResilienceAdaptive Control

Academic Context

#Multi-Agent Systems#Robotics#Reinforcement Learning#Mission Planning#Autonomous Systems

Commercial Potential

Potential Products

Autonomous mission planning software for robot fleetsOn-board replanning modules for robotic systems

Target Industries

AerospaceDefenseLogisticsExploration (Space, Underwater)Search and Rescue

Use Case Examples

Coordinated exploration of unknown terrains by drone swarmsAdaptive mission execution for underwater inspection robotsDynamic task allocation for ground robots in disaster zones

Competitive Edge

Provides a more adaptive and cooperative planning solution for multi-robot systems compared to centralized or single-robot planning approaches.

Market Opportunity

Growing, driven by increasing adoption of autonomous systems in various sectors.

Revenue Models

Licensing of planning softwareIntegration services for robotic systems

Resource Requirements

Compute Needs

High, for onboard computation during real-time replanning.

Data Requirements

Requires mission parameters, task definitions, environmental models, and robot capabilities.

Deployment Constraints

Limited onboard computational resources, real-time decision-making requirements, and communication constraints.

Scalability

Scalability depends on the complexity of the mission, number of robots, and computational resources available.

Production Readiness

Maturity Level

Research

Time to Market

Medium-term, for integration into specialized robotic systems.

Patent Potential

Moderate, for the novel problem formulation and specific RL algorithms.

View Full Paper Back to Papers