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Autori principali: Chen, Yuankun, Nie, Zifei, Gong, Xun, Hu, Yunfeng, Chen, Hong
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2512.19447
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author Chen, Yuankun
Nie, Zifei
Gong, Xun
Hu, Yunfeng
Chen, Hong
author_facet Chen, Yuankun
Nie, Zifei
Gong, Xun
Hu, Yunfeng
Chen, Hong
contents Differentiable optimal control, particularly differentiable nonlinear model predictive control (NMPC), provides a powerful framework that enjoys the complementary benefits of machine learning and control theory. A key enabler of differentiable optimal control is the computation of derivatives of the optimal trajectory with respect to problem parameters, i.e., trajectory derivatives. Previous works compute trajectory derivatives by solving a differential Karush-Kuhn-Tucker (KKT) system, and achieve this efficiently by constructing an equivalent auxiliary system. However, we find that directly exploiting the matrix structures in the differential KKT system yields significant computation speed improvements. Motivated by this insight, we propose FastDOC, which applies a Gauss-Newton approximation of Hessian and takes advantage of the resulting block-sparsity and positive semidefinite properties of the matrices involved. These structural properties enable us to accelerate the computationally expensive matrix factorization steps, resulting in a factor-of-two speedup in theoretical computational complexity, and in a synthetic benchmark FastDOC achieves up to a 180% time reduction compared to the baseline method. Finally, we validate the method on an imitation learning task for human-like autonomous driving, where the results demonstrate the effectiveness of the proposed FastDOC in practical applications.
format Preprint
id arxiv_https___arxiv_org_abs_2512_19447
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Gauss-Newton-Induced Structure-Exploiting Algorithm for Differentiable Optimal Control
Chen, Yuankun
Nie, Zifei
Gong, Xun
Hu, Yunfeng
Chen, Hong
Systems and Control
Differentiable optimal control, particularly differentiable nonlinear model predictive control (NMPC), provides a powerful framework that enjoys the complementary benefits of machine learning and control theory. A key enabler of differentiable optimal control is the computation of derivatives of the optimal trajectory with respect to problem parameters, i.e., trajectory derivatives. Previous works compute trajectory derivatives by solving a differential Karush-Kuhn-Tucker (KKT) system, and achieve this efficiently by constructing an equivalent auxiliary system. However, we find that directly exploiting the matrix structures in the differential KKT system yields significant computation speed improvements. Motivated by this insight, we propose FastDOC, which applies a Gauss-Newton approximation of Hessian and takes advantage of the resulting block-sparsity and positive semidefinite properties of the matrices involved. These structural properties enable us to accelerate the computationally expensive matrix factorization steps, resulting in a factor-of-two speedup in theoretical computational complexity, and in a synthetic benchmark FastDOC achieves up to a 180% time reduction compared to the baseline method. Finally, we validate the method on an imitation learning task for human-like autonomous driving, where the results demonstrate the effectiveness of the proposed FastDOC in practical applications.
title A Gauss-Newton-Induced Structure-Exploiting Algorithm for Differentiable Optimal Control
topic Systems and Control
url https://arxiv.org/abs/2512.19447