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Main Authors: Pasetsky, Myles, Lin, Jiawei, Guo, Bradley, Dean, Sarah
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.07761
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author Pasetsky, Myles
Lin, Jiawei
Guo, Bradley
Dean, Sarah
author_facet Pasetsky, Myles
Lin, Jiawei
Guo, Bradley
Dean, Sarah
contents High-altitude balloons (HABs) are common in scientific research due to their wide range of applications and low cost. Because of their nonlinear, underactuated dynamics and the partial observability of wind fields, prior work has largely relied on model-free reinforcement learning (RL) methods to design near-optimal control schemes for station-keeping. These methods often compare only against hand-crafted heuristics, dismissing model-based approaches as impractical given the system complexity and uncertain wind forecasts. We revisit this assumption about the efficacy of model-based control for station-keeping by developing First-Order Model Predictive Control (FOMPC). By implementing the wind and balloon dynamics as differentiable functions in JAX, we enable gradient-based trajectory optimization for online planning. FOMPC outperforms a state-of-the-art RL policy, achieving a 24% improvement in time-within-radius (TWR) without requiring offline training, though at the cost of greater online computation per control step. Through systematic ablations of modeling assumptions and control factors, we show that online planning is effective across many configurations, including under simplified wind and dynamics models.
format Preprint
id arxiv_https___arxiv_org_abs_2511_07761
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle High-Altitude Balloon Station-Keeping with First Order Model Predictive Control
Pasetsky, Myles
Lin, Jiawei
Guo, Bradley
Dean, Sarah
Robotics
High-altitude balloons (HABs) are common in scientific research due to their wide range of applications and low cost. Because of their nonlinear, underactuated dynamics and the partial observability of wind fields, prior work has largely relied on model-free reinforcement learning (RL) methods to design near-optimal control schemes for station-keeping. These methods often compare only against hand-crafted heuristics, dismissing model-based approaches as impractical given the system complexity and uncertain wind forecasts. We revisit this assumption about the efficacy of model-based control for station-keeping by developing First-Order Model Predictive Control (FOMPC). By implementing the wind and balloon dynamics as differentiable functions in JAX, we enable gradient-based trajectory optimization for online planning. FOMPC outperforms a state-of-the-art RL policy, achieving a 24% improvement in time-within-radius (TWR) without requiring offline training, though at the cost of greater online computation per control step. Through systematic ablations of modeling assumptions and control factors, we show that online planning is effective across many configurations, including under simplified wind and dynamics models.
title High-Altitude Balloon Station-Keeping with First Order Model Predictive Control
topic Robotics
url https://arxiv.org/abs/2511.07761