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Main Authors: Jian, Tong, Dai, Tianyu, Yu, Tao
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.07173
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author Jian, Tong
Dai, Tianyu
Yu, Tao
author_facet Jian, Tong
Dai, Tianyu
Yu, Tao
contents LLMs have shown strong in-context learning (ICL) abilities, but have not yet been extended to signal processing systems. Inspired by their design, we have proposed for the first time ICL using transformer models applicable to motor feedforward control, a critical task where classical PI and physics-based methods struggle with nonlinearities and complex load conditions. We propose a transformer based model architecture that separates signal representation from system behavior, enabling both few-shot finetuning and one-shot ICL. Pretrained on a large corpus of synthetic linear and nonlinear systems, the model learns to generalize to unseen system dynamics of real-world motors only with a handful of examples. In experiments, our approach generalizes across multiple motor load configurations, transforms untuned examples into accurate feedforward predictions, and outperforms PI controllers and physics-based feedforward baselines. These results demonstrate that ICL can bridge synthetic pretraining and real-world adaptability, opening new directions for data efficient control of physical systems.
format Preprint
id arxiv_https___arxiv_org_abs_2602_07173
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Learning Nonlinear Systems In-Context: From Synthetic Data to Real-World Motor Control
Jian, Tong
Dai, Tianyu
Yu, Tao
Machine Learning
Systems and Control
LLMs have shown strong in-context learning (ICL) abilities, but have not yet been extended to signal processing systems. Inspired by their design, we have proposed for the first time ICL using transformer models applicable to motor feedforward control, a critical task where classical PI and physics-based methods struggle with nonlinearities and complex load conditions. We propose a transformer based model architecture that separates signal representation from system behavior, enabling both few-shot finetuning and one-shot ICL. Pretrained on a large corpus of synthetic linear and nonlinear systems, the model learns to generalize to unseen system dynamics of real-world motors only with a handful of examples. In experiments, our approach generalizes across multiple motor load configurations, transforms untuned examples into accurate feedforward predictions, and outperforms PI controllers and physics-based feedforward baselines. These results demonstrate that ICL can bridge synthetic pretraining and real-world adaptability, opening new directions for data efficient control of physical systems.
title Learning Nonlinear Systems In-Context: From Synthetic Data to Real-World Motor Control
topic Machine Learning
Systems and Control
url https://arxiv.org/abs/2602.07173