Discrete choice in the presence of numerical uncertainties

Debasmita Lohar; Eva Darulova; Sylvie Putot; Eric Goubault

doi:10.1109/TCAD.2018.2857320

Discrete choice in the presence of numerical uncertainties

Debasmita Lohar
, Eva Darulova
, Sylvie Putot
, Eric Goubault

Max Planck Institute for Software Systems

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Numerical uncertainties from noisy inputs or finite-precision roundoff errors are unavoidable on resource-constrained systems. While techniques exist to compute worst-case bounds on these errors for arithmetic operations, these approaches do not generalize to programs which take discrete decisions. In this case, the more interesting quantity is the probability of the program making the wrong decision. In this paper, we study two approaches to compute a guaranteed bound on this probability: 1) exact probabilistic inference and 2) probabilistic static analysis. By themselves, they provide accuracy and scalability, respectively, but unfortunately not at the same time. We propose an extension to the latter approach which allows us to bound the probability tightly and fully automatically while scaling to small but interesting embedded examples.

langue originale	Anglais
Numéro d'article	8416700
Pages (de - à)	2381-2392
Nombre de pages	12
journal	IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems
Volume	37
Numéro de publication	11
Les DOIs	https://doi.org/10.1109/TCAD.2018.2857320
état	Publié - 1 nov. 2018

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10.1109/TCAD.2018.2857320

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abstract = "Numerical uncertainties from noisy inputs or finite-precision roundoff errors are unavoidable on resource-constrained systems. While techniques exist to compute worst-case bounds on these errors for arithmetic operations, these approaches do not generalize to programs which take discrete decisions. In this case, the more interesting quantity is the probability of the program making the wrong decision. In this paper, we study two approaches to compute a guaranteed bound on this probability: 1) exact probabilistic inference and 2) probabilistic static analysis. By themselves, they provide accuracy and scalability, respectively, but unfortunately not at the same time. We propose an extension to the latter approach which allows us to bound the probability tightly and fully automatically while scaling to small but interesting embedded examples.",

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AU - Goubault, Eric

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AB - Numerical uncertainties from noisy inputs or finite-precision roundoff errors are unavoidable on resource-constrained systems. While techniques exist to compute worst-case bounds on these errors for arithmetic operations, these approaches do not generalize to programs which take discrete decisions. In this case, the more interesting quantity is the probability of the program making the wrong decision. In this paper, we study two approaches to compute a guaranteed bound on this probability: 1) exact probabilistic inference and 2) probabilistic static analysis. By themselves, they provide accuracy and scalability, respectively, but unfortunately not at the same time. We propose an extension to the latter approach which allows us to bound the probability tightly and fully automatically while scaling to small but interesting embedded examples.

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KW - floating-point

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KW - static analysis

KW - uncertainty

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JF - IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems

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Discrete choice in the presence of numerical uncertainties

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