A new problem qualification based on approximate KKT conditions for Lipschitzian optimization with application to bilevel programming
A new problem qualification based on approximate KKT conditions for Lipschitzian optimization with application to bilevel programming
When dealing with general Lipschitzian optimization problems, there are many problem classes where even weak constraint qualifications fail at local minimizers. In contrast to a constraint qualification, a problem qualification does not only rely on the constraints but also on the objective function to guarantee that a local minimizer is a Karush-Kuhn-Tucker (KKT) point. For example, calmness in the sense of Clarke is a problem qualification. In this article, we introduce the Subset Mangasarian-Fromovitz Condition (subMFC). This new problem qualification is derived by means of a nonsmooth version of the approximate KKT conditions, which hold at every local minimizer without further assumptions. A comparison with existing constraint and problem qualifications reveals that subMFC is strictly weaker than quasinormality and can hold even if the local error bound condition, the cone-continuity property, the Guignard constraint qualification and calmness are violated. Furthermore, we emphasize the power of the new problem qualification within the context of bilevel optimization. More precisely, under mild assumptions on the problem data, we suggest a version of subMFC that is tailored to the lower-level value function reformulation. It turns out that this new condition can be satisfied even if the widely used partial calmness condition does not hold.
math.OC
Käming, Isabella
983e9452-d259-4b48-b0b8-705dfa06e176
Fischer, Andreas
36c6e6ff-f3aa-4b32-8f61-ded55736e925
Zemkoho, Alain B.
30c79e30-9879-48bd-8d0b-e2fbbc01269e
Käming, Isabella
983e9452-d259-4b48-b0b8-705dfa06e176
Fischer, Andreas
36c6e6ff-f3aa-4b32-8f61-ded55736e925
Zemkoho, Alain B.
30c79e30-9879-48bd-8d0b-e2fbbc01269e
Käming, Isabella, Fischer, Andreas and Zemkoho, Alain B.
(2025)
A new problem qualification based on approximate KKT conditions for Lipschitzian optimization with application to bilevel programming.
Optimization.
(doi:10.1080/02331934.2025.2554857).
Abstract
When dealing with general Lipschitzian optimization problems, there are many problem classes where even weak constraint qualifications fail at local minimizers. In contrast to a constraint qualification, a problem qualification does not only rely on the constraints but also on the objective function to guarantee that a local minimizer is a Karush-Kuhn-Tucker (KKT) point. For example, calmness in the sense of Clarke is a problem qualification. In this article, we introduce the Subset Mangasarian-Fromovitz Condition (subMFC). This new problem qualification is derived by means of a nonsmooth version of the approximate KKT conditions, which hold at every local minimizer without further assumptions. A comparison with existing constraint and problem qualifications reveals that subMFC is strictly weaker than quasinormality and can hold even if the local error bound condition, the cone-continuity property, the Guignard constraint qualification and calmness are violated. Furthermore, we emphasize the power of the new problem qualification within the context of bilevel optimization. More precisely, under mild assumptions on the problem data, we suggest a version of subMFC that is tailored to the lower-level value function reformulation. It turns out that this new condition can be satisfied even if the widely used partial calmness condition does not hold.
Text
2407.16422v2
- Accepted Manuscript
Text
A new problem qualification based on approximate KKT conditions for Lipschitzian optimization with application to bilevel programming
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Accepted/In Press date: 22 August 2024
e-pub ahead of print date: 5 November 2025
Keywords:
math.OC
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Local EPrints ID: 508926
URI: http://eprints.soton.ac.uk/id/eprint/508926
ISSN: 0233-1934
PURE UUID: 44996c3a-8865-4ce7-b742-4947ac15abcc
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Date deposited: 06 Feb 2026 17:43
Last modified: 07 Mar 2026 03:29
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Author:
Isabella Käming
Author:
Andreas Fischer
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