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Hauptverfasser: Clark, Abram H., Mudrik, Liraz, Kawamura, Colton, Redder, Nathan C., Hespanha, João P., Kaminer, Isaac
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2603.10743
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author Clark, Abram H.
Mudrik, Liraz
Kawamura, Colton
Redder, Nathan C.
Hespanha, João P.
Kaminer, Isaac
author_facet Clark, Abram H.
Mudrik, Liraz
Kawamura, Colton
Redder, Nathan C.
Hespanha, João P.
Kaminer, Isaac
contents Designing autonomous drone swarms is hampered by a vast design space spanning platform, algorithmic, and numerical-strength choices. We perform large-scale agent-based simulations in three canonical scenarios: swarm-on-swarm battle, cooperative area search with attrition, and pursuit of scattering targets. We demonstrate how dimensional-analysis and data-scaling can be leveraged to collapse performance data onto scaling functions that are mathematically simple, yet counterintuitive and therefore difficult to predict a priori. These scaling laws reveal success-failure boundaries, including sharp break points which we show can be framed as an ``effective swarm size.'' Additionally, we show how this technique can be used to quantify trade-offs between agent count and platform parameters such as velocity, sensing or weapon range, and attrition rate. Furthermore, we show the benefits of embedding an optimal path planning loop within this framework, which can qualitatively improve the scaling laws that govern the outcome. The methods we demonstrate are highly flexible and would enable rapid, budget-aware sizing and algorithm selection for large autonomous swarms.
format Preprint
id arxiv_https___arxiv_org_abs_2603_10743
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Scaling and Trade-offs in Multi-agent Autonomous Systems
Clark, Abram H.
Mudrik, Liraz
Kawamura, Colton
Redder, Nathan C.
Hespanha, João P.
Kaminer, Isaac
Systems and Control
Designing autonomous drone swarms is hampered by a vast design space spanning platform, algorithmic, and numerical-strength choices. We perform large-scale agent-based simulations in three canonical scenarios: swarm-on-swarm battle, cooperative area search with attrition, and pursuit of scattering targets. We demonstrate how dimensional-analysis and data-scaling can be leveraged to collapse performance data onto scaling functions that are mathematically simple, yet counterintuitive and therefore difficult to predict a priori. These scaling laws reveal success-failure boundaries, including sharp break points which we show can be framed as an ``effective swarm size.'' Additionally, we show how this technique can be used to quantify trade-offs between agent count and platform parameters such as velocity, sensing or weapon range, and attrition rate. Furthermore, we show the benefits of embedding an optimal path planning loop within this framework, which can qualitatively improve the scaling laws that govern the outcome. The methods we demonstrate are highly flexible and would enable rapid, budget-aware sizing and algorithm selection for large autonomous swarms.
title Scaling and Trade-offs in Multi-agent Autonomous Systems
topic Systems and Control
url https://arxiv.org/abs/2603.10743