An Analytical Framework for Determining the Minimum Size of Highly Miniaturized Satellites: PlanarSats

Mehmet Şevket Uludağ; Alim Rüstem Aslan

doi:10.3390/aerospace12100876

An Analytical Framework for Determining the Minimum Size of Highly Miniaturized Satellites: PlanarSats

Mehmet Şevket Uludağ^*, Alim Rüstem Aslan

^*Corresponding author for this work

Department of Astronautical Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

This paper introduces a power-driven systems engineering methodology for the early-phase design of highly miniaturized satellites: PlanarSats. We derive an analytical framework linking power requirements, contingency policies, solar-cell performance, and subsystem integration to determine the absolute minimum satellite size. Through idealized and detailed case studies, we explore the trade-offs inherent in subsystem selection and integration constraints. Sensitivity analysis identifies critical factors affecting minimum area and operational envelopes. Our framework provides a clear tool for balancing functionality, reliability, and physical limits in next-generation ultra-small satellite missions.

Original language	English
Article number	876
Journal	Aerospace
Volume	12
Issue number	10
DOIs	https://doi.org/10.3390/aerospace12100876
Publication status	Published - Oct 2025

Bibliographical note

Publisher Copyright:
© 2025 by the authors.

Keywords

attosat
ChipSat
femtosat
PlanarSat
small satellite
systems engineering

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10.3390/aerospace12100876

Cite this

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title = "An Analytical Framework for Determining the Minimum Size of Highly Miniaturized Satellites: PlanarSats",

abstract = "This paper introduces a power-driven systems engineering methodology for the early-phase design of highly miniaturized satellites: PlanarSats. We derive an analytical framework linking power requirements, contingency policies, solar-cell performance, and subsystem integration to determine the absolute minimum satellite size. Through idealized and detailed case studies, we explore the trade-offs inherent in subsystem selection and integration constraints. Sensitivity analysis identifies critical factors affecting minimum area and operational envelopes. Our framework provides a clear tool for balancing functionality, reliability, and physical limits in next-generation ultra-small satellite missions.",

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author = "Uludağ, \{Mehmet {\c S}evket\} and Aslan, \{Alim R{\"u}stem\}",

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doi = "10.3390/aerospace12100876",

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AB - This paper introduces a power-driven systems engineering methodology for the early-phase design of highly miniaturized satellites: PlanarSats. We derive an analytical framework linking power requirements, contingency policies, solar-cell performance, and subsystem integration to determine the absolute minimum satellite size. Through idealized and detailed case studies, we explore the trade-offs inherent in subsystem selection and integration constraints. Sensitivity analysis identifies critical factors affecting minimum area and operational envelopes. Our framework provides a clear tool for balancing functionality, reliability, and physical limits in next-generation ultra-small satellite missions.

KW - attosat

KW - ChipSat

KW - femtosat

KW - PlanarSat

KW - small satellite

KW - systems engineering

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ER -

An Analytical Framework for Determining the Minimum Size of Highly Miniaturized Satellites: PlanarSats

Abstract

Bibliographical note

Keywords

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