Multiobjective optimization and particle-in-cell simulation of cusped field thrusters for microsatellite platforms

Suk H. Yeo; Hideaki Ogawa; Paul Matthias; Daniel Kahnfeld; Ralf Schneider

doi:10.2514/1.A34584

Multiobjective optimization and particle-in-cell simulation of cusped field thrusters for microsatellite platforms

Suk H. Yeo, Hideaki Ogawa, Paul Matthias, Daniel Kahnfeld, Ralf Schneider

Space Systems Engineering

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

6 Citations (Scopus)

Abstract

A multiobjective design optimization (MDO) study has been conducted to characterize and maximize the performance of the downscaled cusped field thruster with respect to thrust, total efficiency, and specific impulse characterized by common design parameters: Anode voltage, anode current, mass flow rate, and geometric configuration. Particle-in-cell (PIC) simulations have been performed for the selected design points identified in MDO study for verification by accurately accounting for phenomena and performance losses that originate from uncertainties and complexities associated with the thruster design and physics. The fidelity of the models employed in MDOhas been enhanced owing to the new physical insights gained from the detailed analysis of the PIC results. The prediction errors associated with uncertainties such as the beam current and divergence angle have been reduced to within 5%.

Original language	English
Pages (from-to)	603-611
Number of pages	9
Journal	Journal of Spacecraft and Rockets
Volume	57
Issue number	3
DOIs	https://doi.org/10.2514/1.A34584
Publication status	Published - 2020

All Science Journal Classification (ASJC) codes

Aerospace Engineering
Space and Planetary Science

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10.2514/1.A34584

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abstract = "A multiobjective design optimization (MDO) study has been conducted to characterize and maximize the performance of the downscaled cusped field thruster with respect to thrust, total efficiency, and specific impulse characterized by common design parameters: Anode voltage, anode current, mass flow rate, and geometric configuration. Particle-in-cell (PIC) simulations have been performed for the selected design points identified in MDO study for verification by accurately accounting for phenomena and performance losses that originate from uncertainties and complexities associated with the thruster design and physics. The fidelity of the models employed in MDOhas been enhanced owing to the new physical insights gained from the detailed analysis of the PIC results. The prediction errors associated with uncertainties such as the beam current and divergence angle have been reduced to within 5%.",

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AU - Yeo, Suk H.

AU - Ogawa, Hideaki

AU - Matthias, Paul

AU - Kahnfeld, Daniel

AU - Schneider, Ralf

PY - 2020

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AB - A multiobjective design optimization (MDO) study has been conducted to characterize and maximize the performance of the downscaled cusped field thruster with respect to thrust, total efficiency, and specific impulse characterized by common design parameters: Anode voltage, anode current, mass flow rate, and geometric configuration. Particle-in-cell (PIC) simulations have been performed for the selected design points identified in MDO study for verification by accurately accounting for phenomena and performance losses that originate from uncertainties and complexities associated with the thruster design and physics. The fidelity of the models employed in MDOhas been enhanced owing to the new physical insights gained from the detailed analysis of the PIC results. The prediction errors associated with uncertainties such as the beam current and divergence angle have been reduced to within 5%.

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Multiobjective optimization and particle-in-cell simulation of cusped field thrusters for microsatellite platforms

Abstract

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