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Network-related problems in M2ACS. Mihai Anitescu. Multifaceted Mathematics for Complex Energy Systems ( M2ACS) Project Director: Mihai Anitescu, Argonne National Lab. Goals:
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Network-related problems in M2ACS Mihai Anitescu
Multifaceted Mathematics for Complex Energy Systems (M2ACS)Project Director: Mihai Anitescu, Argonne National Lab • Goals: • Taking a holistic view, develop deep mathematical understanding and effective algorithms at the intersection of multiple math areas for problems with multiple math facets (dynamics, graph theory, integer/continous, probabilistic …) for CES • We do integrative mathematics to support a DOE grand challengewhile advancing math itself. • Integrated Novel Mathematics Research: • Predictive modeling • Mathematics of decisions • Scalable algorithms for optimization and dynamic simulation • Integrative frameworks (90/10 vs 10/90 • Mission; we identify the math patterns that will enable the CSE applications. • Long-Term DOE Impact: • Development of new mathematics at the intersection of multiple mathematical sub-domains • Addresses a broad class of math patterns from complex energy systems, such as : • Planning for power grid and related infrastructure • Analysis and design for renewable energy integration PICTURE Team: Argonne National Lab (Lead), Pacific Northwest National Lab, Sandia National Lab, University of Wisconsin, University of Chicago
Leads to new challenges and math in and draws expertise from Optimization Probability/Stochastics/Statistics/Uncertainty Quantification Dynamical Systems Linear Algebra Graph Theory Data Analysis Scalable Algorithms (Dynamics, Nonlinear Solvers, Optimization ...) Domain-Specific Languages. Go to ”Insert (View) | Header and Footer" to add your organization, sponsor, meeting name here; then, click "Apply to All"
One Challenge Class: Graph Theory Go to ”Insert (View) | Header and Footer" to add your organization, sponsor, meeting name here; then, click "Apply to All"
Energy networks challenges • Energy networks math challenges: • Scalable dynamics and optimization solvers for network constraints • Models of network evolution • Emerging temporal and spatial network-scales. • Probabilistic model of network failure. • Synthetic networks to address privacy, competitiveness and incomplete data issues • Estimation and calibration of probabilistic network structure models. • …… Go to ”Insert (View) | Header and Footer" to add your organization, sponsor, meeting name here; then, click "Apply to All"
New fundamental graph theory opportunity? • How do we concisely but comprehensively for our goals parameterize graph structure? • What are probabilistic models for graph theory with “few parameters” that capture the fundamentals of end-goal behaviors (including evolution)? • What are graph metrics which are “sufficient statistics” (both state and topology) for our problems? –stats mechanics analogy: the only “predictable observables” • How do we know the resulting models are consistent and sample from such models – heterogeneous materials analogy? • Solution will likely involve: probability, data analysis, optimization, graph theory, dynamical systems • (John Doyle’s ) Hourglass Go to ”Insert (View) | Header and Footer" to add your organization, sponsor, meeting name here; then, click "Apply to All"