SCvx-Frank-Wolfe Algorithm

Danil Berrah; Damien Hoareau; Alexandre Chapoutot

doi:10.23919/ECC65951.2025.11186948

SCvx-Frank-Wolfe Algorithm

Danil Berrah
, Damien Hoareau
, Alexandre Chapoutot

Résultats de recherche: Le chapitre dans un livre, un rapport, une anthologie ou une collection › Contribution à une conférence › Revue par des pairs

Résumé

Convex optimization algorithms are increasingly used in embedded trajectory planning for safety-critical systems, requiring verification to meet safety standards. Previous research has shown that formal verification methods can be applied to convex solvers for linear problems. This paper explores a specific implementation of the successive convexification approach for trajectory planning using linear programming. We focus on a new implementation of the successive convexification algorithm based on the Frank-Wolfe method (FW-SCVX), aiming at demonstrating that it maintains algorithm performance and is suitable for embedded systems. We also analyze the convergence of the FW-SCVX algorithm and provide numerical evaluations to support our proposal. This work contributes to the formal verification of advanced trajectory planning algorithms in safety-critical embedded systems.

langue originale	Anglais
titre	2025 European Control Conference, ECC 2025
Editeur	Institute of Electrical and Electronics Engineers Inc.
Pages	737-742
Nombre de pages	6
Edition	2025
ISBN (Electronique)	9783907144121
Les DOIs	https://doi.org/10.23919/ECC65951.2025.11186948
état	Publié - 1 janv. 2025
Evénement	2025 European Control Conference, ECC 2025 - Thessaloniki, Grcce Durée: 24 juin 2025 → 27 juin 2025

Une conférence

Une conférence	2025 European Control Conference, ECC 2025
Pays/Territoire	Grcce
La ville	Thessaloniki
période	24/06/25 → 27/06/25

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10.23919/ECC65951.2025.11186948

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title = "SCvx-Frank-Wolfe Algorithm",

abstract = "Convex optimization algorithms are increasingly used in embedded trajectory planning for safety-critical systems, requiring verification to meet safety standards. Previous research has shown that formal verification methods can be applied to convex solvers for linear problems. This paper explores a specific implementation of the successive convexification approach for trajectory planning using linear programming. We focus on a new implementation of the successive convexification algorithm based on the Frank-Wolfe method (FW-SCVX), aiming at demonstrating that it maintains algorithm performance and is suitable for embedded systems. We also analyze the convergence of the FW-SCVX algorithm and provide numerical evaluations to support our proposal. This work contributes to the formal verification of advanced trajectory planning algorithms in safety-critical embedded systems.",

author = "Danil Berrah and Damien Hoareau and Alexandre Chapoutot",

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AU - Berrah, Danil

AU - Hoareau, Damien

AU - Chapoutot, Alexandre

PY - 2025/1/1

Y1 - 2025/1/1

N2 - Convex optimization algorithms are increasingly used in embedded trajectory planning for safety-critical systems, requiring verification to meet safety standards. Previous research has shown that formal verification methods can be applied to convex solvers for linear problems. This paper explores a specific implementation of the successive convexification approach for trajectory planning using linear programming. We focus on a new implementation of the successive convexification algorithm based on the Frank-Wolfe method (FW-SCVX), aiming at demonstrating that it maintains algorithm performance and is suitable for embedded systems. We also analyze the convergence of the FW-SCVX algorithm and provide numerical evaluations to support our proposal. This work contributes to the formal verification of advanced trajectory planning algorithms in safety-critical embedded systems.

AB - Convex optimization algorithms are increasingly used in embedded trajectory planning for safety-critical systems, requiring verification to meet safety standards. Previous research has shown that formal verification methods can be applied to convex solvers for linear problems. This paper explores a specific implementation of the successive convexification approach for trajectory planning using linear programming. We focus on a new implementation of the successive convexification algorithm based on the Frank-Wolfe method (FW-SCVX), aiming at demonstrating that it maintains algorithm performance and is suitable for embedded systems. We also analyze the convergence of the FW-SCVX algorithm and provide numerical evaluations to support our proposal. This work contributes to the formal verification of advanced trajectory planning algorithms in safety-critical embedded systems.

UR - https://www.scopus.com/pages/publications/105030974424

U2 - 10.23919/ECC65951.2025.11186948

DO - 10.23919/ECC65951.2025.11186948

M3 - Conference contribution

AN - SCOPUS:105030974424

SP - 737

EP - 742

BT - 2025 European Control Conference, ECC 2025

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 2025 European Control Conference, ECC 2025

Y2 - 24 June 2025 through 27 June 2025

ER -

SCvx-Frank-Wolfe Algorithm

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