13th International Conference on Modeling, Optimization and Simulation - MOSIM 2020

Comité d’organisation: Université Internationale d’Agadir – Agadir (Maroc) Laboratoire Conception Fabrication Commande – Metz (France)Session RS-1 “Simulation et Optimisation” / “Simulation and Optimization” Session RS-2 “Planification des Besoins Matières Pilotée par la Demande” / ”Demand-Driven Material Requirements Planning” Session RS-3 “Ingénierie de Systèmes Basées sur les Modèles” / “Model-Based System Engineering” Session RS-4 “Recherche Opérationnelle en Gestion de Production” / "Operations Research in Production Management" Session RS-5 "Planification des Matières et des Ressources / Planification de la Production” / “Material and Resource Planning / Production Planning" Session RS-6 “Maintenance Industrielle” / “Industrial Maintenance” Session RS-7 "Etudes de Cas Industriels” / “Industrial Case Studies" Session RS-8 "Données de Masse / Analyse de Données” / “Big Data / Data Analytics" Session RS-9 "Gestion des Systèmes de Transport” / “Transportation System Management" Session RS-10 "Economie Circulaire / Développement Durable" / "Circular Economie / Sustainable Development" Session RS-11 "Conception et Gestion des Chaînes Logistiques” / “Supply Chain Design and Management" Session SP-1 “Intelligence Artificielle & Analyse de Données pour la Production 4.0” / “Artificial Intelligence & Data Analytics in Manufacturing 4.0” Session SP-2 “Gestion des Risques en Logistique” / “Risk Management in Logistics” Session SP-3 “Gestion des Risques et Evaluation de Performance” / “Risk Management and Performance Assessment” Session SP-4 "Indicateurs Clés de Performance 4.0 et Dynamique de Prise de Décision” / ”4.0 Key Performance Indicators and Decision-Making Dynamics" Session SP-5 "Logistique Maritime” / “Marine Logistics" Session SP-6 “Territoire et Logistique : Un Système Complexe” / “Territory and Logistics: A Complex System” Session SP-7 "Nouvelles Avancées et Applications de la Logique Floue en Production Durable et en Logistique” / “Recent Advances and Fuzzy-Logic Applications in Sustainable Manufacturing and Logistics" Session SP-8 “Gestion des Soins de Santé” / ”Health Care Management” Session SP-9 “Ingénierie Organisationnelle et Gestion de la Continuité de Service des Systèmes de Santé dans l’Ere de la Transformation Numérique de la Société” / “Organizational Engineering and Management of Business Continuity of Healthcare Systems in the Era of Numerical Society Transformation” Session SP-10 “Planification et Commande de la Production pour l’Industrie 4.0” / “Production Planning and Control for Industry 4.0” Session SP-11 “Optimisation des Systèmes de Production dans le Contexte 4.0 Utilisant l’Amélioration Continue” / “Production System Optimization in 4.0 Context Using Continuous Improvement” Session SP-12 “Défis pour la Conception des Systèmes de Production Cyber-Physiques” / “Challenges for the Design of Cyber Physical Production Systems” Session SP-13 “Production Avisée et Développement Durable” / “Smart Manufacturing and Sustainable Development” Session SP-14 “L’Humain dans l’Usine du Futur” / “Human in the Factory of the Future” Session SP-15 “Ordonnancement et Prévision de Chaînes Logistiques Résilientes” / “Scheduling and Forecasting for Resilient Supply Chains

Considerations for the interdisciplinary development of environmental system models

Effective decision making and policy development requires holistic consideration of the modelling context. This thesis explores how consideration of multiple disciplinary perspectives and concerns lead to an integrative model development process for the purpose of socio-environmental systems (SES) management. The research is presented through two frames: (1) Integrated Environmental Model (IEM) development through a System-of-Systems (SoS) approach, and (2) the socio-technical considerations within an interdisciplinary modelling process. The presented research incorporates the perspectives of the modelling, systems engineering, and software development paradigms. IEMs are developed for the purpose of integrating knowledge across the various disciplines involved, whereas traditional approaches focus on single systems within the SES, such as hydrology, economics, social dynamics, or climatic drivers. Use of IEMs allows for the consideration of the flow-on effects due to system changes and interaction, and how these may affect long-term SES behaviour. Pathways that are robust - i.e., lead to beneficial or desirable outcomes - under a range of plausible but uncertain conditions can then be identified and assessed. An interconnected network of system models thus makes up an SoS model allowing consideration of higher-order effects. In practice, however, the decisions and approaches taken in developing constituent models may influence integrated system behaviour once coupled. The socio-technical modelling concerns within the SoS/SES modelling context, including the methods to assess and manage model validity, complexity, and uncertainty, with respect to model purpose and intended outcomes are explored through a series of publications. This thesis contributes to the growing body of knowledge through: 1. An expansive overview of the currently available software for model uncertainty and sensitivity analysis, and the techniques they encompass 2. An integrated environmental model for the Lower Campaspe catchment in North-Central Victoria, Australia. The model explores long-term implications of water management decisions and potential policy changes (primarily through an agricultural lens), including conjunctive use of surface and groundwater under a range of uncertain futures. 3. Demonstration of a property-based sensitivity analysis approach to model diagnostics that combines software testing and sensitivity analysis to validate model behaviour. The approach is useful as a first-pass screening tool. Failure to reproduce expected model behaviour indicates issues with the model to be corrected and avoids the necessity of more computationally demanding diagnostics. 4. A pragmatic step-by-step framework for the sensitivity analysis of spatially distributed environmental models 5. Exploration and discussion of the modelling practices, issues and challenges that arise when dealing with the various influences and effects of scale within the interdisciplinary SoS context through a socio-technical lens. The discussion leads to a call for a grander vision for SoS-IEM modelling (and commensurate funding) to better enable interdisciplinary, and integrative, socio-environmental research to occur. 6. A shared reflexive account of two case studies that draws out the considerations and decisions regarding scale to arrive at five shared lessons learnt to foster an effective interdisciplinary modelling process. The key conclusion is the need for researchers involved in SoS modelling of SESs to actively consider and address cross-disciplinary concerns through improved interdisciplinary communication, documentation practices, and explicit consideration of the interplay between defined scales and resulting influence on uncertainty. Integrative consideration of these would then lower or avoid barriers that hamper the development and application of integrated environmental system models