Methodology for estimating the probability of failure by sliding in concrete gravity dams in the context of risk analysis, Structural Safety, pp.36-37, 2012. ,
Optimisation fiabiliste de la conception et de la maintenance des stuctures, 2008. ,
URL : https://hal.archives-ouvertes.fr/tel-00726003
Benchmark study of numerical methods for reliability-based design optimization, Structural and multidisciplinary optimization, vol.41, pp.277-294, 2010. ,
Orthogonal Polynomials and Special Functions, CBMS-NSF Regional Conference Series in Applied Mathematics, p.116, 1975. ,
Some Basic Hypergeometric Orthogonal Polynomials that Generalize Jacobi Polynomials, p.68, 1985. ,
Chemo-hygro-mechanical modelling and numerical simulation of concrete deterioration caused by alkali-silica reaction, International Journal for Numerical and Analytical Methods in Geomechanics, vol.28, pp.689-714, 2004. ,
Mathematical model for kinetics of alkali-silica reaction in concrete, Cement and Concrete Research, vol.30, pp.270-277, 2000. ,
Mechanical effects of alkali silica reaction in concrete studied by SEM-image analysis, 2007. ,
Eléments finis stochastiques : approches intrusive et non intrusive pour des analyses de fiabilité, 2005. ,
Adaptive sparse polynomial chaos expansions for uncertainty propagation and sensitivity analysis, Methods: Université, 2009. ,
URL : https://hal.archives-ouvertes.fr/tel-00440197
Adaptive sparse polynomial chaos expansions for uncertainty propagation and sensitivity analysis, 2009. ,
URL : https://hal.archives-ouvertes.fr/tel-00440197
Sparse polynomial chaos expansions and adaptive stochastic finite elements using a regression approach, Comptes Rendus Mécanique, vol.336, pp.518-523, 2008. ,
An adaptive algorithm to build up sparse polynomial chaos expansions for stochastic finite element analysis, Probabilistic Engineering Mechanics, vol.25, pp.183-197, 2010. ,
Efficient computation of global sensitivity indices using sparse polynomial chaos expansions, Reliability Engineering & System Safety, vol.95, pp.1216-1229, 2010. ,
Adaptive sparse polynomial chaos expansion based on least angle regression, Journal of Computational Physics, vol.230, pp.2345-2367, 2011. ,
A review of continuum damage modelling for dam analysis, European Journal of Environmental and Civil Engineering, vol.14, pp.805-822, 2010. ,
URL : https://hal.archives-ouvertes.fr/hal-01724663
Asymptotic Approximations for Multinormal Integrals, Journal of Engineering Mechanics, vol.110, pp.357-366, 1984. ,
Alkali-silica reaction: A method to quantify the reaction degree, Cement and Concrete Research, vol.32, pp.1199-1206, 2002. ,
The Orthogonal Development of Non-Linear Functionals in Series of Fourier-Hermite Functionals, Annals of Mathematics, vol.48, pp.385-392, 1947. ,
Modelling, computer-assisted simulations, and mapping of dangerous phenomena for hazard assessment, vol.22, pp.1509-1518, 2007. ,
Modeling of Induced Mechanical Effects of Alkali-Aggregate Reactions, Cement and Concrete Research, vol.28, pp.251-260, 1998. ,
Orthotropic modelling of alkali-aggregate reaction in concrete structures: numerical simulations, Mechanics of Materials, vol.35, 2003. ,
Evaluation probabiliste de la sécurité structurale des barragespoids, 2009. ,
A computational linear elastic fracture mechanicsbased model for alkali-silica reaction, Cement and Concrete Research, vol.42, pp.613-625, 2012. ,
URL : https://hal.archives-ouvertes.fr/hal-00843899
Microporomechanics study of anisotropy of ASR under loading, Cement and Concrete Research, vol.63, pp.143-157, 2014. ,
URL : https://hal.archives-ouvertes.fr/hal-01157339
Simplified Model for the Transport of Alkali-Silica Reaction Gel in Concrete Porosity, Journal of Advanced Concrete Technology, vol.12, pp.1-6, 2014. ,
URL : https://hal.archives-ouvertes.fr/hal-00940139
Generalized Sobol sensitivity indices for dependent variables: numerical methods, Journal of Statistical Computation and Simulation, vol.85, pp.1306-1333, 2015. ,
URL : https://hal.archives-ouvertes.fr/hal-01980685
Advances in solution methods for reliability-based design optimization, Structural Design Optimization Considering Uncertainties, pp.251-280, 2008. ,
Structural reliability under non-Gaussian stochastic behavior, Computers & Structures, vol.82, pp.1113-1121, 2004. ,
Development and validation of a 3D computional tool to describe damage and fracture due to Alcali-Silica Reaction in concrete structures, École nationale supérieure des mines, 2006. ,
A chemo-thermo-damage model for the analysis of concrete dams affected by alkali-silica reaction, Mechanics of Materials, vol.41, pp.210-230, 2009. ,
Réflexion sur la réaction alcali-silice: Colloque METL-DRAST sur l'alcaliréaction ESPCI, 1999. ,
Structural Performance: Probability-Based Assessment, p.448, 2011. ,
The new morris method: An efficient second order screening method, Reliability Engineering and System Safety, vol.78, pp.109-115, 2002. ,
The New Morris Method: An efficient secondorder screening method, Reliability Engineering and System Safety, vol.78, pp.77-83, 2002. ,
Multimodel-Based Diagnosis of Hydraulic Dams, Journal of Computing in Civil Engineering, vol.31, p.4017024, 2017. ,
A Knowledge Formalization and Aggregation-Based Method for the Assessment of Dam Performance, Computer-Aided Civil and Infrastructure Engineering, vol.25, pp.171-184, 2010. ,
URL : https://hal.archives-ouvertes.fr/hal-00585649
A dam assessment support system based on physical measurements, sensory evaluations and expert judgements, Measurement, vol.44, pp.192-201, 2011. ,
URL : https://hal.archives-ouvertes.fr/hal-00581096
Probabilistic finite element analysis of concrete gravity dams, Advances in Engineering Software, vol.29, pp.97-104, 1998. ,
Journee ACI du 17 mai 1999-Paris Conséquences de la réaction Alcali-Granulats sur les barrages exploited par EDF, Revue Française de Génie Civil, vol.4, pp.577-589, 2000. ,
Structures granulaires et formulation des bétons, 2000. ,
The chemistry of 'alkali-aggregate' reaction, Cement and Concrete Research, vol.11, pp.1-9, 1981. ,
Fiabilité et mécanique méthodes FORM/SORM et couplages avec des codes d'éléments finis par des surfaces de réponse adaptatives, 1996. ,
A study of expansion due to alkali -silica reaction as conditioned by the grain size of the reactive aggregate, Cement and Concrete Research, vol.4, pp.591-607, 1974. ,
Structural Reliability Methods, p.384, 1996. ,
Materials properties model of aging concrete, 2005. ,
The mechanism of the alkali-silica reaction, BULLETIN DES LABORATOIRES DES PONTS ET CHAUSSEES, 1998. ,
Thermodynamic and kinetic approach to the alkalisilica reaction. Part 1: Concepts, Cement and Concrete Research, vol.22, pp.941-948, 1992. ,
Thermodynamic and kinetic approach to the alkalisilica reaction. Part 2: Experiment, Cement and Concrete Research, vol.23, pp.93-103, 1993. ,
Experimental and modelling study of the alkali-silica-reaction in concrete, 2009. ,
Micro-mechanical modelling of alkali-silicareaction-induced degradation using the AMIE framework, Cement and Concrete Research, vol.40, pp.517-525, 2010. ,
Effects of uniaxial stress on alkali-silica reaction induced expansion of concrete, Cement and Concrete Research, vol.42, pp.567-576, 2012. ,
Fiabilité des structures. Toulouse. Fiabilité résiduelle des ouvrages en béton par réaction alcali-granulat Application au barrage de Song Loulou, 2013. ,
Surfaces de réponse physiques et polynomiales, Fiabilité des ouvrages: Sûreté, variabilité, maintenance, sécurité, 2011. ,
The projection gradient algorithm with error control for structural reliability, Engineering Structures, vol.32, pp.3725-3733, 2010. ,
Least angle regression, The Annals of Statistics, vol.32, pp.407-499, 2004. ,
Design of hydraulic gates, 2014. ,
Literature review of modelling approaches for ASR in concrete: a new perspective, European Journal of Environmental and Civil Engineering, pp.1-21, 2017. ,
Modelling the structural behaviour of a dam affected by alkalisilica reaction, Communications in Numerical Methods in Engineering, vol.22, pp.1-12, 2006. ,
Analyse de sensibilité globale et polynômes de chaos pour l'estimation des paramètres : application aux transferts en milieu poreux, 2014. ,
Macroscopic model of concrete subjected to alkali-aggregate reaction, Cement and Concrete Research, vol.34, pp.495-505, 2004. ,
Aide à la gestion des ouvrages atteints de réactions de gonflement interne, Guide Technique des LPC, 2003. ,
Report on the Diagnosis, Prognosis, and Mitigation of Alkali-Silica Reaction (ASR) in Transportation Structures, 2010. ,
An Analytical Study Concerning Prediction of Concrete Expansion due to Alkali-Silica Reaction, 1994. ,
A comparison of methods for chemical assessment of reactive silica in concrete aggregates by selective dissolution, Cement and Concrete Composites, vol.37, pp.82-94, 2013. ,
URL : https://hal.archives-ouvertes.fr/hal-01724654
Contribution to the requalification of ASR-damaged structures: Assessment of the ASR advancement in aggregates, 2010. ,
A three-step method for the recovery of aggregates from concrete, Construction and Building Materials, vol.45, pp.262-269, 2013. ,
URL : https://hal.archives-ouvertes.fr/hal-01724655
Alkali-silica reaction (ASR) expansion: Pessimum effect versus scale effect, Cement and Concrete Research, vol.44, pp.25-33, 2013. ,
URL : https://hal.archives-ouvertes.fr/hal-01724652
Mechanism of damage for the alkali-silica reaction, Cement and Concrete Research, vol.36, pp.395-400, 2006. ,
Effect of Multiaxial Stresses on Alkali-Silica Reaction Damage of Concrete, ACI Materials Journal, vol.114, 2017. ,
Multiaxial Expansion-Stress Relationship for Alkali Silica Reaction-Affected Concrete, ACI Materials Journal, vol.114, 2017. ,
Dimensionnement semi-probabiliste des coques minces de révolution susceptibles d'instabilités géométriques, 2002. ,
Ingredients for a general purpose stochastic finite elements implementation, Computer Methods in Applied Mechanics and Engineering, vol.168, pp.106-112, 1999. ,
Numerical solution of spectral stochastic finite element systems, Computer Methods in Applied Mechanics and Engineering, vol.129, pp.289-303, 1996. ,
Stochastic Finite Elements: A Spectral Approach, Revised Edition, p.240, 2012. ,
Mechanical behavior of concretes damaged by alkali-silica reaction, Cement and Concrete Research, vol.38, pp.993-1004, 2008. ,
Modelling of alkali-silica reaction under multi-axial load, 2013. ,
Osmotic pressure and the swelling of gels, Cement and Concrete Research, vol.9, pp.515-517, 1979. ,
Alcali-réaction dans les structures en béton Mécanisme, pathologie et prévention, 2008. ,
Diffusion of ions through hardened cement pastes, Cement and Concrete Research, vol.11, pp.751-757, 1981. ,
Concrete modelling for expertise of structures affected by alkali aggregate reaction, Cement and Concrete Research, vol.40, pp.502-507, 2010. ,
URL : https://hal.archives-ouvertes.fr/hal-01724666
Diagnostic et mise en sécurité du barrage de, 2013. ,
Studies Relating To the Mechanism by Which the Alkali-Aggregate Reaction Produces expansion in concrete, ACI Journal Proceedings, vol.40, 1944. ,
Simplified reliability analysis of multi hazard risk in gravity dams via machine learning techniques, Archives of Civil and Mechanical Engineering, vol.18, pp.592-610, 2018. ,
Support vector machine based reliability analysis of concrete dams, Soil Dynamics and Earthquake Engineering, vol.104, pp.276-295, 2018. ,
An Exact and Invariant First Order Reliability Format, Journal of Engineering Mechanics, vol.100, 1974. ,
Mechanical behavior model for ASR-affected dam concrete under service load: formulation and verification, Materials and Structures, vol.42, pp.201-212, 2009. ,
Particle size of aggregate and its influence upon the expansion caused by the alkali-silica reaction, Magazine of Concrete Research, vol.31, pp.235-242, 1979. ,
Improvement of second-order reliability estimates by importance sampling, Journal of Engineering Mechanics, vol.114, pp.2195-2199, 1988. ,
Optimal condition-based maintenance decisions for systems with dependent stochastic degradation of components, Reliability Engineering & System Safety, vol.121, pp.276-288, 2014. ,
Modeling of Thermomechanical Effects of Alkali-Silica Reaction, Journal of Engineering Mechanics, vol.125, issue.476, p.4, 1999. ,
Collocation-based stochastic finite element analysis for random field problems, Probabilistic Engineering Mechanics, vol.22, pp.194-205, 2007. ,
Alkali-silica reaction, pessimum effects and pozzolanic effect, Cement and Concrete Research, vol.39, pp.716-726, 2009. ,
Modified model of alkali-silica reaction, Cement and Concrete Research, vol.37, pp.1291-1297, 2007. ,
Alcali-réaction dans les barrages en béton -Aperçu général et recommandations, 1991. ,
Introduction to Sensitivity Analysis, Handbook of Uncertainty Quantification, 2017. ,
Etudes de sécurité de l'aménagement hydroélectrique de Songloulou au Cameroun, 2011. ,
Uncertainty Analysis of Transport-transformation Models, p.396, 1999. ,
Reclassification of alkali aggregate reaction, 2012. ,
Development of dam safety management system, Advances in Engineering Software, vol.40, pp.554-563, 2009. ,
Glascrete"-Concrete with Glass Aggregate, ACI Materials Journal, vol.97, 2000. ,
A new interpretation of alkali-silica reaction and expansion mechanism in concrete, Chemistry, pp.40-44, 1988. ,
Reliability Analysis of Spillway Gate Systems, 2013. ,
Nonlinear finite element reliability analysis of Concrete-Faced Rockfill (CFR) dams under static effects, Applied Mathematical Modelling, vol.36, pp.5229-5248, 2012. ,
ASR gel composition and expansive pressure in mortars under restraint, Cement and Concrete Composites, vol.26, pp.47-56, 2004. ,
Alkali-silica reaction: Kinetics of chemistry of pore solution and calcium hydroxide content in cementitious system, Cement and Concrete Research, vol.71, pp.36-45, 2015. ,
Morris method of sensitivity analysis applied to assess the importance of input variables on urban water supply yield -A case study, Journal of Hydrology, vol.477, pp.17-32, 2013. ,
Hypergeometric Orthogonal Polynomials, Hypergeometric Orthogonal Polynomials and Their q-Analogues, 2010. ,
The Askey-scheme of hypergeometric orthogonal polynomials and its q-analogue, 1996. ,
Reliability analysis of high-dimensional models using low-rank tensor approximations, Probabilistic Engineering Mechanics, vol.46, pp.18-36, 2016. ,
URL : https://hal.archives-ouvertes.fr/hal-01428991
Derivative-Based Global Sensitivity Measures, Handbook of Uncertainty Quantification, 2017. ,
URL : https://hal.archives-ouvertes.fr/hal-01079358
, Structural effects of ASR in France on real and laboratory structures, 2000.
Apports combinés de l'expérimentation et de la modélisation à la compréhension de l'alcali-réaction et de ses effets mécaniques, Ecole Nationale des Ponts et Chaussées, 1997. ,
A Stochastic Projection Method for Fluid Flow: II. Random Process, Journal of Computational Physics, vol.181, pp.9-44, 2002. ,
Evolution under stress of a concrete affected by aarapplication to the feasilbility of strengthening a bridge by prestressing, Proceedings of the 9th International Conference on Alkal-Aggregate Reaction, vol.108, pp.599-606, 1992. ,
Contributions à la modélisation de la dépendance stochastique, 2013. ,
A generalization of the Nataf transformation to distributions with elliptical copula, Probabilistic Engineering Mechanics, vol.24, pp.172-178, 2009. ,
E-modulus of the alkali-silica-reaction product determined by micro-indentation, Construction and Building Materials, vol.44, pp.221-227, 2013. ,
Finite element analysis of concrete swelling due to alkaliaggregate reactions in dams, Computers & Structures, vol.60, issue.95, pp.440-448, 1996. ,
Fiabilité des structures: Couplage mécano-fiabiliste statique, 2005. ,
Hydraulic gates and valves: in free surface flow and submerged outlets, 2001. ,
Modélisation chimico-mécanique du comportement des béetons affectés par la réeaction d'alcali-silice et expertise numéerique des ouvrages d'art déegradés, pp.1-219, 2002. ,
ASR expansions in concrete under triaxial confinement, 2017. ,
Mesure expérimentale de la cinétique de formation d'un gel silicocalcique, produit de la réaction alcalis-silice, Cement and Concrete Research, vol.27, pp.128-130, 1997. ,
A brief description of the Levenberg-Marquardt algorithm implemented by levmar, Foundation of Research and Technology, vol.4, p.6, 2005. ,
Surrogate models for oscillatory systems using sparse polynomial chaos expansions and stochastic time warping, vol.5, pp.540-571, 2016. ,
URL : https://hal.archives-ouvertes.fr/hal-01421106
An Algorithm for Least-Squares Estimation of Nonlinear Parameters, Journal of the Society for Industrial and Applied Mathematics, vol.11, pp.431-441, 1963. ,
Galerkin methods for linear and nonlinear elliptic stochastic partial differential equations, Computer Methods in Applied Mechanics and Engineering, vol.194, pp.1295-1331, 2005. ,
Application de la mécanique de l'endommagement au comportement non linéaire et à la rupture du béton de structure, 1984. ,
Search-based importance sampling, Structural Safety, vol.9, pp.90003-90011, 1990. ,
State-of-practice for the nonlinear structural analysis of dams at the bureau of reclamation, 2006. ,
Contribution à l'étude de la redondance dans les ponts: analyse des mécanismes de défaillance par surfaces de réponse, École nationale des ponts et chaussées, 2007. ,
Contribution a? l'etude de la redondance dans les ponts: analyse des me?anismes de defaillance par surfaces de re?onse, École nationale des ponts et chaussées, 2007. ,
Prediction error estimation: a comparison of resampling methods, Bioinformatics, vol.21, pp.3301-3307, 2005. ,
Determination of the elastic properties of amorphous materials: Case study of alkali-silica reaction gel, Cement and Concrete Research, vol.54, pp.55-60, 2013. ,
Modélisation des réactions de gonflement interne des bétons avec prise en compte des couplages poro-mécaniques et chimiques, 2017. ,
Impact of stresses and restraints on ASR expansion, Construction and Building Materials, vol.140, pp.58-74, 2017. ,
URL : https://hal.archives-ouvertes.fr/hal-01724648
Factorial Sampling Plans for Preliminary Computational Experiments, Technometrics, vol.33, p.161, 1991. ,
Coupled effects of aggregate size and alkali content on ASR expansion, Cement and Concrete Research, vol.38, pp.350-359, 2008. ,
URL : https://hal.archives-ouvertes.fr/hal-01006003
Évaluation Expérimentale Et Théorique Des Effets Mécaniques De L'Alcali-Réaction Sur Des Structures Modèles, 2003. ,
Alain Jeanpierre, & François Toutlemonde, Revue Européenne de Génie Civil, vol.9, pp.1219-1247, 2005. ,
Multi-scale analysis of alkali-silica reaction (ASR): Impact of alkali leaching on scale effects affecting expansion tests, Cement and Concrete Research, vol.81, pp.122-133, 2016. ,
URL : https://hal.archives-ouvertes.fr/hal-01708236
Chemo-mechanical modeling for prediction of alkali silica reaction (ASR) expansion, Cement and Concrete Research, vol.39, pp.490-500, 2009. ,
URL : https://hal.archives-ouvertes.fr/hal-01724667
Effect of applied stresses on alkali-silica reaction-induced expansions, Cement and Concrete Research, vol.36, 2006. ,
URL : https://hal.archives-ouvertes.fr/hal-01727410
Response Surface Methodology, Encyclopedia of Biopharmaceutical Statistics, 2013. ,
Modelling of the mechanical behavior of concrete using a coupled multi-physics approach (chemical-mechanical coupling): application to alkali-silica reaction, Modelling of the mechanical behavior of concrete using a coupled multi-physics approach (chemica, 2009. ,
Détermination des distributions dont les marges sont données, Comptes rendus de l'académie des sciences, vol.225, pp.42-43, 1962. ,
Contribution à l'approche probabiliste de la durabilité des structures en béton soumise à la carbonatation, 2015. ,
, Algorithmes probabilistes appliqués à la durabilité et à la mécanique des ouvrages de Génie Civil
An adaptive response surface method based on double weighted regression, Probabilistic Engineering Mechanics, vol.31, 2007. ,
Adaptive response surface method based on a double weighted regression technique, Probabilistic Engineering Mechanics, vol.24, pp.135-143, 2009. ,
Development of stresses in concrete structures with alkali-silica reactions, Materials and Structures, vol.26, pp.152-158, 1993. ,
La durabilité des bétons: bases scientifiques pour la formulation de bétons durables dans leur environnement, 2008. ,
Béton-Dispositions pour prévenir les phénomènes d'alcali-réaction. Association Française de Normalisation (AFNOR), pp.18-464, 2014. ,
Modeling of alkali-silica reaction in concrete: a review, Frontiers of Structural and Civil Engineering, vol.6, pp.1-18, 2012. ,
Methodology for risk analysis of dam gates and associated operating equipment using fault tree analysis, 2005. ,
Composition et volume molaire apparent des gels Ca Si, une approche expérimentale, Comptes Rendus Geoscience, vol.335, pp.951-958, 2003. ,
Modeling alkali-silica reaction in non-isothermal, partially saturated cement based materials, Computer Methods in Applied Mechanics and Engineering, vol.225, pp.95-115, 2012. ,
Elastic and structural properties of alkaline-calcium silica hydrogels, Journal of Materials Research, vol.20, pp.344-349, 2005. ,
Different manifestations of the alkali-silica reaction in concrete according to the reaction kinetics of the reactive aggregate, Cement and Concrete Research, vol.36, pp.1148-1156, 2006. ,
Alkali-silica reactivity mechanisms of gel formation and expansion, 1992. ,
Chemical modelling of Alkali Silica reaction: Influence of the reactive aggregate size distribution, Materials and Structures/Materiaux et Constructions, vol.40, pp.229-239, 2007. ,
URL : https://hal.archives-ouvertes.fr/hal-00434194
Etude de la degradation des ouvrages en beton atteints par la reaction alcali-silice -approche experimentale et modelisation numerique des degradations dans un environnement hydro-chemo-mecanique variable, 2003. ,
URL : https://hal.archives-ouvertes.fr/tel-00006479
Alkali-Silica Reaction, Part I: Use of the Double-Layer Theory to Explain the Behavior of Reaction-Product Gels, ACI Materials Journal, vol.94, 1997. ,
Variance-Based Sensitivity Analysis: Theory and Estimation Algorithms, Handbook of Uncertainty Quantification, 2017. ,
Reliability analysis-a review and some perspectives, Structural Safety, vol.23, pp.365-395, 2001. ,
Structural Reliability Analysis and Prediction, Third Edition, 2018. ,
Remarks on a multivariate transformation, The annals of mathematical statistics, vol.23, pp.470-472, 1952. ,
Approche probabiliste pour la justification par analyse des structures spatiales, 2011. ,
An improved sampling strategy based on trajectory design for application of the Morris method to systems with many input factors, Environmental Modelling & Software, vol.37, pp.103-109, 2012. ,
Simulation and the Monte Carlo Method, p.401, 2011. ,
Global {S}ensitivity {S}nalysis. {T}he {P}rimer, 2008. ,
Sensitivity Analysis in Practice: a Guide to Assessing Scientific Models, Journal of Chemical Information and Modeling, vol.53, p.232, 2004. ,
Evaluation of the stiffness damage test (SDT) as a tool for assessing damage in concrete due to ASR: test loading and output responses for concretes incorporating fine or coarse reactive aggregates, Cement and concrete research, vol.56, pp.213-229, 2014. ,
Comparative study of a chemo-mechanical modeling for alkali silica reaction (ASR) with experimental evidences, Construction and Building Materials, vol.72, pp.301-315, 2014. ,
URL : https://hal.archives-ouvertes.fr/hal-01724650
Numerical Modeling of AAR, p.326, 2014. ,
Constitutive Model for Alkali-Aggregate Reactions, ACI Materials Journal, vol.103, 2006. ,
Design guidelines for spillway gates, Journal of Hydraulic Engineering, vol.122, pp.155-165, 1996. ,
Une modélisation de la réaction alcalis-granulat intégrant une description des phénomènes aléatoires locaux, Materials and Structures, vol.28, pp.373-383, 1995. ,
Modélisation probabiliste du comportement de matériaux et de structures en génie civil. Cachan, Ecole normale supérieure, 1995. ,
Combination of Structural Monitoring and Laboratory Tests for Assessment of AlkaliAggregate Reaction Swelling: Application to Gate Structure Dam, ACI Materials Journal, vol.106, 2009. ,
URL : https://hal.archives-ouvertes.fr/hal-02087641
Modélisation physico-chimique de la réaction alcaligranulat: apport au calcul des structures dégradées, Revue Française de Génie Civil, vol.1, pp.445-481, 1997. ,
Swelling Concrete in Dams and Hydraulic Structures: DSC 2017, p.380, 2017. ,
Concrete creep modelling for structural applications: nonlinearity, multi-axiality, hydration, temperature and drying effects, Cement and Concrete Research, vol.79, pp.301-315, 2016. ,
URL : https://hal.archives-ouvertes.fr/hal-01714901
Multiple failure modes analysis of the dam system by means of line sampling simulation, Optik-International Journal for Light and Electron Optics, vol.127, pp.4710-4715, 2016. ,
Modeling AlkaliSilica Reaction Using Image Analysis and Finite Element Analysis, Advanced Materials Research, 2011. ,
Alkali-Aggregate Reaction in Concrete: A World Review, 2017. ,
On an alternative global sensitivity estimators, Proceedings of SAMO, pp.40-42, 1995. ,
Influences on the alkali-aggregate reaction in concrete, 1975. ,
Cross-validatory choice and assessment of statistical predictions, Journal of the royal statistical society. Series B (Methodological, pp.111-147, 1974. ,
Swelling Properties of Synthetic Alkali Silica Gels, Journal of the American Ceramic Society, vol.64, pp.652-655, 1981. ,
Global sensitivity analysis using polynomial chaos expansions, Reliability Engineering & System Safety, vol.93, pp.964-979, 2008. ,
URL : https://hal.archives-ouvertes.fr/hal-01432217
A Mathematical Model for the Pessimum Size Effect of ASR in Concrete, Concrete Science and Engineering, vol.4, pp.23-34, 2002. ,
The Alkali-Silica Reaction in Concrete, p.353, 2002. ,
An efficient method for parametric uncertainty analysis of numerical geophysical models, Journal of Geophysical Research: Atmospheres, vol.102, pp.21925-21932, 1997. ,
Cement chemistry, 1997. ,
Alkali-Aggregate Reactivity (AAR) Facts Book, 2013. ,
FHWA-HIF-12-046 Alkali-Silica Reactivity Surveying and Tracking Guidelines, 2012. ,
Mactaquac generating station intake and spillway remedial measures, 1994. ,
Thermo-Chemo-Mechanics of ASR Expansion in Concrete Structures, Journal of Engineering Mechanics, vol.126, pp.233-242, 2000. ,
URL : https://hal.archives-ouvertes.fr/hal-00586622
ASR expansion behavior in reinforced concrete: experimentation and numerical modeling for practical application, 2017. ,
Mechanism of alkali-silica reaction and the significance of calcium hydroxide, Cement and Concrete Research, vol.21, issue.91, p.90115, 1991. ,
Reliability-based assessment of concrete dam stability, 2010. ,
System reliability of concrete dams with respect to foundation stability: application to a spillway, Journal of Geotechnical and Geoenvironmental Engineering, vol.139, pp.308-319, 2012. ,
The Homogeneous Chaos, American Journal of Mathematics, vol.60, p.897, 1938. ,
State-of-the art report: Key parameters influencing the alkali aggregate reaction, 2006. ,
A new stochastic approach to transient heat conduction modeling with uncertainty, International Journal of Heat and Mass Transfer, vol.46, pp.4681-4693, 2003. ,
Influence of aggregate size and aggregate size grading on ASR expansion, Cement and Concrete Research, vol.29, pp.1393-1396, 1999. ,
, Annexe B Résultats complémentaires des analyses de sensibilités
,
,
,
,
,
,
,
,
, , vol.212, pp.9379715464-02
, 9215756466E-05, vol.6, pp.929934263-929934266
, 5462113460E-05 -1,1697536944E-02 -1,1381937699E,8610560103E-05, vol.2, pp.136523511-136523513
8 : Coefficients du modèle de substitution de calcul de ?V(t) en conditions accélérées (4/4) 166 5 ,
, 5866069972E-05, vol.5, p.9614759969
, , p.226
,
,
, D.1. Neuf exemples détaillés de détermination de fonctions poids de, 2006.
, = ?10, = ?30, =2] MPa se trouvant à l'intérieur 1, Exemple, vol.1, issue.1, pp.1917721726-1917721730
, .73205?1)(1.73205?7), vol.2, pp.6182740666-05
, .73205?0)(1.73205?2)(1.73205?5) 144 -4,3259135190E-04 (1.73205?4)(1.73205?5)(1.73205?6) 108 -1,4607466685E-04 (1.73205?0)(1.73205?4)(1.73205?5) 145 3,8974994188E-04 (1.73205?4)(1.73205?5)(1.73205?7) 109 3,8113074320E-05 (1.73205?0)(1.73205?5)(1.73205?6) 146 2,6693568208E-04 (1.73205?4)(1.73205?5)(1.73205?8) 110 -3,2917219111E-05 (1.73205?0)(1.73205?5)(1.73205?7) 147 -1,0340505804E-04 (1.73205?5)(1.73205?6)(1.73205?7) 111 -1, 9764273556E-04 (1.73205?3)(1.73205?6)(1.73205?7) 106 -8,3451155467E-05 (1.73205?0)(1.73205?1)(1.73205?5) 143 7,5947719550E-05 (1.73205?3)(1.73205?6)(1.73205?13), vol.107, pp.9366095983-05
, + 26.1184?8 5 60, vol.5
, 73205?0)(1.73205?4) 62 -1, pp.3620343955-05
, 5099164423E-05 (1.73205?1)(1.73205?4), vol.63
, 3931135779E-05 (1.73205?1)(1.73205?8), vol.64, pp.8305831479-06
, 73205?2)(1.73205?4) 65 6, pp.5504388050-06
, 8207841840E-05 (1.73205?2)(1.73205?5), vol.66
, 9323070279E-04 (1.73205?3)(1.73205?4), vol.67, pp.30-31
, 73205?3)(-1.11803 + 3.3541?5 8585860739E-05 (1.73205?3)(1.73205?6) 69 -2, 8634739241E-05 (1.73205?3)(1.73205?5) 68, vol.2, pp.7875529324-05
, 6082284369E-05 (1.73205?3)(1.73205?7) 70, vol.8, pp.1783736203-1783736209
, .73205?3)(1.73205?8) 71 -1, pp.3726628660-04
, .73205?4)(1.73205?5) 73, vol.8, pp.8371816692-06
, Coefficients du modèle de substitution du déplacement au point d'auscultation (6/7) 0 5,1380543843E+00, vol.9, pp.37-40
, 3288148141E-03 (1.73205?5)(1.73205?7), vol.3, pp.2562526343-02
, 1.11803 + 3.3541?0 2 )(1.73205?2) 10, vol.46, pp.6004879569-03
, 1099181361E-02 (1.73205?0)(1.73205?2), vol.57
, 1.73205?3) 60 -5,1445371524E-03 (1.73205?0)(1.73205?4)(1.73205?7) 24 -1
, .73205?3)(1.73205?5) 70, vol.2, pp.5701726203-02
Coefficients du model de substitution du déplacement maximal de la console 42 -8, pp.73205-73218 ,
, ,73205?2)(1,73205?3) 5 -3,9176038032E-03 1,73205?4 44 -3,4820922335E-04 (1,73205?2)(1,73205?4) 6 -4, vol.8, pp.73205-73210
, 2236093849E-04 (1,73205?2)(1,73205?6) 8 -4,3257695544E-03 1,73205?7 47 1, pp.73205-73212
, 8632938111E-05 (1,73205?2)(1,73205?12) 11 -3,4790197749E-05 1,73205?11 50 -8,4657934068E-05, vol.3, pp.73205-73218
, ,73205?3)(1,73205?5) 14 -6,0824306644E-05 -1,11803 + 3,3541?0 2 53 1, vol.8, pp.73205-73212
, ,73205?4)(1,73205?6) 21 5,5115011511E-04 -1,11803 + 3, 8761865351E-04 (1,73205?4)(1,73205?5) 20 8,6552953317E-05 -1,11803 + 3,3541?6, vol.3, pp.5131315334-04, 11803.
, 8335080688E-05 (1,73205?0)(1,73205?2) 66, vol.8, pp.73205-73213
, ,73205?5)(1,73205?9) 29 -7,0091137476E-05 (1,73205?0)(1,73205?4) 68 -8,6455743044E-05 (1,73205?5)(1,73205?12) 30 -2,1242992183E-04 (1,73205?0)(1,73205?5) 69 -1, vol.9, pp.73205-73218
, ,73205?6)(1,73205?9) 33 -1,5415373300E-04 (1,73205?1)(1,73205?2) 72 8,6260604898E-05 (1,73205?6)(1,73205?12) 34 -5,6430482227E-04 (1,73205?1)(1,73205?3) 73 1,9638899641E-04 (1,73205?6)(1,73205?13) 35 -2,3405880896E-04 (1,73205?1)(1,73205?4) 74 -7,4436197507E-05 (1,73205?7)(1,73205?12) 36 -2,6366954166E-04 (1,73205?1)(1,73205?5) 75 -1, 3462145630E-05 (1,73205?0)(1,73205?8) 71, vol.3, pp.73205-73214
, Coefficients du, vol.12, pp.73205-73209, 11803.
, ,73205?5) 118 6,2040420014E-05 (1,73205?1)(1,73205?2)(1,73205?5) 80 -5,1824455853E-05 (-1,11803 + 3,3541?1 2 )(1,73205?6) 119 -5, vol.7, pp.73205-73211, 11803.
, 11803 + 3,3541?4 2 ) 129 1,1607484060E-04 (1,73205?1)(1,73205?5)(1,73205?8) 91 -8, pp.73205-73207
, ,73205?5) 131 -2,9335150615E-04 (1,73205?2)(1,73205?3)(1,73205?5) 93 -6, vol.3, pp.73205-73210, 11803.
, 11803 + 3,3541?5 2 ) 136 1,4013160386E-04 (1,73205?2)(1,73205?5)(1,73205?7) 98 -2,2768389426E-04 (1,73205?3)(-1,11803 + 3,3541?5 2 ) 137 -1, vol.2, pp.73205-73214
, 11803 + 3,3541?5 2 ) 138 -1,7318752710E-05 (1,73205?2)(1,73205?5)(1,73205?12) 100 -1,3258639206E-04 (-1,11803 + 3, vol.5, pp.73205-73218
, ,73205?4)(-1,11803 + 3,3541?6 2 ) 142 -5, 3922002351E-05 (1,73205?3)(1,73205?4, vol.5, pp.73205-73212
, 6400554370E-05 (1,73205?3)(1,73205?4, vol.5, pp.73205-73213, 11803.
, 5486610813E-05 (1,73205?3)(1,73205?5, vol.3, pp.73205-73213, 11803.
, ,73205?4)(-1,11803 + 3,3541?8 2 ) 148 5, vol.9, pp.73205-73218
, ,73205?4)(1,73205?5)(1,73205?7) 112 3,7162336888E-05 (1,73205?0)(1,73205?2)(1,73205?5) 151 2,2144707198E-04 (1,73205?4)(1,73205?5)(1,73205?8) 113 -1,1959361116E-04 (1,73205?0)(1,73205?4)(1,73205?5) 152 -8,3988515528E-05 (1,73205?5)(1,73205?6)(1,73205?7) 114 2,9928227052E-05 (1,73205?0)(1,73205?5)(1,73205?6) 153 4,0420127199E-05 (1,73205?5)(1,73205?7)(1,73205?8) 115 -2,5353417574E-05 (1,73205?0)(1,73205?5)(1,73205?7) 154 1,0379723094E-05 (1,73205?6)(1,73205?7)(1,73205?9) 116 -1, 6076134160E-04 (1,73205?4)(1,73205?5)(1,73205?6) 111 -6,9241396981E-05 (1,73205?0)(1,73205?1)(1,73205?5) 150, vol.3, pp.61438-61446, 2007542872-04-01.
, ,73205?3)(1,73205?4)(1,73205?6) 23 5,2150536120E-05 (1,73205?3)(1,73205?6) 60 2,3605601919E-05 (1,73205?3)(1,73205?4)(1,73205?7) 24 -4,0280825369E-05 (1,73205?3)(1,73205?7) 61 1,0431458132E-04 (1,73205?3)(1,73205?4)(1,73205?8) 25 -1,0175855590E-04 (1,73205?3)(1,73205?8) 62 5,4951794576E-05 (1,73205?3)(1,73205?5)(1,73205?8) 26 3,2425424321E-05 (1,73205?3)(1,73205?9) 63 -3,4099330239E-05 (1,73205?3)(1,73205?6)(1,73205?8) 27 9, 0024558964E-05 (1,73205?1)(1,73205?4)(1,73205?8) 20 1,7174689359E-05 (1,73205?0)(1,73205?4) 57 -1,1572954961E-05 (1,73205?2)(1,73205?4)(1,73205?8) 21 -1,4028393318E-04 (1,73205?3)(1,73205?4) 58 5,2081261567E-05 (1,73205?3)(1,73205?4)(1,73205?5), pp.3330154739-05
14 : Coefficients du modèle de substitution du déplacement maximal de la console, vol.1, pp.4403520327-02 ,
, 2832863658E-03 (-1.11803 + 3.3541?2 2 )(1.73205?8) 10, vol.2, pp.56995219-56995220
, 8212708411E-03 -3.96863?5 + 6.61438?5 3 45 6, pp.17-26
, 2096953523E-03 (1.73205?4)(1.73205?5)(1.73205?7) 26 -2,6862647128E-02 (1.73205?4)(1.73205?8) 5 4,0079716488E-01 1.73205?4 27 -2,6510395847E-02 (1.73205?5)(1.73205?8) 6 7, vol.2, pp.55-64
, .73205?1)(1.73205?3)(1.73205?5) 17 -1, pp.39-40
, ,73205?4)(1,73205?9) 5 -2,2041334059E-04 1,73205?4 41 -5,2314371847E-05 (1,73205?5)(1,73205?6) 6 -2, 73205?5, vol.5, issue.1, pp.73205-73212
, 9947737050E-05 (1,73205?5)(1,73205?9) 8 -2, vol.3, pp.73205-73212
, 8495858322E-05, pp.73205-73216
, 3151396957E-05 (1,73205?9)(1,73205?12) 13 -1,6267050572E-04 1,73205?13 49, vol.3, pp.73205-73218
, 8011424834E-05 (1,73205?11, vol.6, pp.73205-73218, 11803.
, 5919674141E-05 (1,73205?12, vol.2, pp.73205-73218, 11803.
, 6717134304E-05 (1,73205?0)(1,73205?5), vol.57, pp.3541-3546, 11803.
, 5467787694E-06 (1,73205?1)(1,73205?2) 58, vol.3, pp.3541-3546, 11803.
, 5183875647E-05 (1,73205?1)(1,73205?3) 59 1,4216108046E-05 (1,73205?3, vol.3, pp.3541-3548, 11803.
, 6769114711E-05 (1,73205?1)(1,73205?6) 60 -1,2881676660E-05 (1,73205?1)(1,73205?3, pp.73205-73210
, 1,73205?4)(1,73205?5) 26 -1,2345113406E-05 (1,73205?1)(1,73205?9) 62 1,2089240004E-05 (1,73205?2)(1,73205?5)(1,73205?7) 27 -3,5310625434E-05 (1,73205?2)(1,73205?3) 63 -2,5221046581E-05 (1,73205?3)(1,73205?4)(1,73205?5) 28 -1,5036602289E-05 (1,73205?2)(1,73205?4) 64 -1,6825867528E-05 (1,73205?3)(1,73205?4)(1,73205?6) 29 -4, 8081318970E-05 (1,73205?1)(1,73205?7) 61, vol.2, pp.73205-73207
, ,73205?3)(1,73205?4) 67 -1,7747383368E-05 (1,73205?3)(1,73205?5)(1,73205?9) 32 -1,0082789068E-04 (1,73205?3)(1,73205?5) 68 -2, 1879170882E-05 (1,73205?3)(1,73205?5)(1,73205?8), pp.73205-73212
, 1,73205?6) 69 1,3597728325E-05 (1,73205?3)(1,73205?6)(1,73205?9) 34 -1,2416049290E-04 (1,73205?3)(1,73205?7) 70 -1, pp.73205-73211
, ,73205?3)(1,73205?6) 22 -1,4736492093E-05 (1,73205?3)(1,73205?8) 23 1,0488607374E-05 (1,73205?4)(1,73205?5) 24 -7,8583016559E-06 (1,73205?4)(1,73205?6) 25 6,6741255960E-06 (1,73205?4)(1,73205?7) 26 2,2069235163E-05 (1,73205?4)(1,73205?8) 27 -4,2723417009E-06 (1,73205?4)(1,73205?11) 28 1,2378225093E-05 (1,73205?5)(1,73205?8) 29 -7,6202817141E-06 (1,73205?6)(1,73205?8) 30 6,6385310740E-06 (1,73205?7)(1,73205?8) 31 -2,0887284372E-05 (1,73205?9)(1,73205?11) 32 -1,7360498215E-05 (1,73205?9)(1,73205?12) 33 1,4147855663E-05 (1,73205?9)(1,73205?13) 34 3, 7245712847E-05 (1,73205?3)(1,73205?9) 71 2,1107095444E-05 (1,73205?4)(1,73205?5)(1,73205?7) 18 -4,5710781013E-06 (1,73205?2)(1,73205?5) 19 -1,4238685373E-05 (1,73205?3)(1,73205?4) 20 -6,9498654253E-06 (1,73205?3)(1,73205?5) 21 5, vol.5, pp.125-133
, ,73205?4)(1,73205?8) 40 4,1506164134E-06 (1,73205?3)(1,73205?5)(1,73205?8) 41 -6, vol.9, pp.73205-73213